An electrical connector assembly for mating with a mating connector assembly. The connector assembly includes a housing with a cable receiving portion and a mating portion. The housing has a first surface and an oppositely facing second surface. The mating portion has a mating projection which extends from the first surface in a direction away from the second surface. The mating projection has a circular cross-sectional configuration. The mating projection has an angled wall which extends from the first surface to a mating face, the angled wall is angled relative to a plane of the first surface and a plane of the mating face. The mating face has contacts which extend therethrough. The contacts has circular engagement sections arranged concentrically about a center of the mating face. A nonconductive coating applied to the angled wall.

A sensor arrangement and cable for use in process automation, including a sensor having at least one sensor element for recording a value in process automation, a first interface for transmitting a measured value depending on the measured value to a second interface, the first interface including a first mechanical, and a cable for transmitting the value to a superordinate unit, the cable including said second interface, which is complementary to the first interface, and a second mechanical coupling complementary to the first mechanical coupling, wherein the second interface and mechanical coupling are arranged in a cable housing, wherein the sensor is detachably connectible to the cable by the first mechanical coupling and the second mechanical coupling, characterized in that the second mechanical coupling is arranged at an angle less than 180° to the longitudinal axis of the cable housing.

There are provided a microphone stand having a connector supporting groove, and a microphone body supported by the microphone stand as a result of insertion of a connector case into the connector supporting groove. A resilient conductive cloth which comes into contact with the connector case is arranged in the connector supporting groove, with the connector case inserted in the connector supporting groove. The conductive cloth is preferably arranged in a ring shape along a lower bottom portion of the annularly formed connector supporting groove. This configuration mitigates rattling generated between the connector supporting groove and the connector case, thereby suppressing generation of a vibration noise due to microphone shaking.

An anti-loosening light device includes a light bulb and a light socket. One end of the light bulb is screwed into the light socket and is detachably connected to the light socket. The light bulb includes a bulb head and a bulb body. The bulb head is connected to the bulb body. The bulb body is provided with a bulb body positioning part. The bulb body positioning part is connected to the light socket. The light socket includes a socket body and socket limiting parts. The socket limiting parts are connected to the socket body. One end of the light bulb is inserted into the socket body. The bulb body positioning part is installed on the socket limiting parts. The bulb body positioning part and the socket limiting parts are engaged with each other.

An appliance cord assembly may include a first cord portion including a plug at one end configured to be received by a wall outlet and a plug mount at the opposite end, a second cord portion including a captive end hardwired to an appliance and a free end connected to a panel mount, the panel mount being configured to connect with the plug mount of the first cord portion to create a conductive engagement with the plug mount, such that in the connected state, the plug mount and the panel mount define a key opening, and a service tool configured to be received by the key opening to disconnect the panel mount and plug mount.

Coaxial connecting devices used for transmitting high frequency electrical signals having two connector elements of generally cylindrical profile, and wherein each of the connector elements has an inner conductor, an insulator, and an outer conductor. In one of the two connector elements that may be of a male or a female orientation has two canted coil spring contacts where at least one of a first spring contact can be retained within at least one first spring groove within a second inner conductor and at least one of a second spring contact is retained within at least one second spring groove within a second outer conductor. The at least one second spring contact can be used as a simultaneous EMI shielding contact and latching, locking, or both latching and locking device.

An electrical connector assembly includes a cable assembly having a cable bundle of cables and a conductive cable shield surrounding and providing electrical shielding for the cable bundle. The cable assembly includes an electrical connector a housing holding contacts and a conductive backshell having a cavity that receives the electrical connector to provide electrical shielding for the electrical connector. The backshell has a cable channel at a rear of the backshell that receives the cable. A ground spring is coupled to the cable and positioned between the cable bundle and the cable shield. The ground spring includes spring members engaging the inner surface of the cable shield and biasing the cable shield radially outward. The ground spring is received in the cable channel and forces the outer surface of the cable shield outward against the backshell to electrically connect the cable shield to the backshell.

An RF connector is provided. The connector includes a first socket member. The first socket member includes a conductive sleeve and end cap. The conductive sleeve includes a top portion, a bottom portion, and a plurality of springs connecting the top portion and the bottom portion. A base inside the conductive sleeve includes a first matching hole configured to match to a first conductive pin of a first plug member. The end cap includes a base and a lip. In a first position, the top portion of the conductive sleeve contacts the base of the end cap and is partially enclosed by the lip of the end cap. The end cap prevents the removal of the conductive sleeve in the first position.

A plug connector includes an insulating housing, and a terminal surrounding the insulating housing. The insulating housing has a fastening portion. Two opposite sides of a top of the fastening portion protrude upward and are arched outward to form two fastening pieces. A fastening slot is formed among a lateral wall, an inner wall and a bottom wall of the terminal. Two portions of a top surface of the lateral wall protrude upward to form two insertion portions. The fastening portion is fastened in the fastening slot. One of the two insertion portions is located between one side of one of the two fastening pieces and one side of the other fastening piece. The other insertion portion is located between the other side of the one of the two fastening pieces and the other side of the other fastening piece.

Embodiments may comprise forming a rigid, tubular outer housing of an electrically conductive material; inserting an electrical cable longitudinally into the outer housing, the electrical cable having an inner conductor and a dielectric jacket surrounding the inner conductor; and, reshaping at least one longitudinal segment of the outer housing to fix the electrical cable inside the outer housing.