An electrical connection device includes a pair of connectors, namely a first connector and a second connector. The first connector includes a housing main body portion, a lock arm, and a cantilever portion. The second connector includes a lock receiving portion and an abutting portion. When the pair of connectors are in the unfitted state, the cantilever portion is located between the housing main body portion and the lock arm so as to be capable of supporting the lock arm. The abutting portion comes into contact with the cantilever portion when the pair of connectors are fitted together, and therefore the cantilever portion undergoes elastic displacement to a position that allows the lock arm to flex toward the housing main body portion.

A connector assembly comprises a first connector and a second connector connectable to each other. The first connector comprises first terminals each having a first contact portion, a first shell having a first mating portion and a first engagement member formed with an engagement recess. The second connector comprises second terminals each having a second contact portion, a second shell having a second mating portion and a second engagement member having an engagement projection. Under a connected state where the first connector and the second connector are connected to each other, the first mating portion and the second mating portion entirely enclose contact areas in a perpendicular plane (YZ-plane) at which the first contact portions are in contact with the second contact portions. Under the connected state, the engagement projection and the engagement recess are engaged with each other to lock the connected state.

A communications connector has a main plug assembly and a wire cap that is configured to terminate a pair of conductors to the pair of contacts by being secured to a side of the main plug assembly in a direction perpendicular to a plane defined by a deflection direction of a latch of the connector. In another embodiment, a communications connector has a main plug assembly and two electrical contacts within the main plug assembly wherein each electrical contact has a first end having a forked receptacle and a second end having an IDC that is configured to have a conductor terminated in a direction perpendicular to a direction of mating insertion and parallel to a plane defined by the contact.

A connector assembly (10) is disclosed in which a connector part (12) and a cable manager part (20) are provided. The cable manager part (20) can be provided with a rear housing (40), a lacing fixture part (30), and a grounding part (50). In one aspect, the grounding part (50) provides grounding contact between an inserted cable (4) and the connector part (12). In one aspect, the grounding part (50) secures the connector part (12) to the rear housing part (40). In one example, a connector assembly (110) is provided with a grounding arrangement (150) including a plurality of deflectable grounding members (152) and provides grounding contact between the inserted cable (4) and the connector part (112). In one aspect, the grounding members (152) each provide two points of contact against the cable (4).

An electrical connector assembly includes a first electrical contact device and a second electrical contact device. The first electrical contact device includes at least one first electrical contact and an actuator movable between a first position and a second position. The second electrical contact device includes at least one second electrical contact device and an interlock feature to engage the actuator when the actuator is in the first position. The actuator is in the first position when the first electrical contact is in electrical communication with a power source, and the actuator is in the second position when the electrical communication between the first electrical contact and the power source is disconnected. When the actuator is in the first position and the second electrical contact engage the first electrical contact, the interlock feature engages the actuator, thereby securing the first electrical contact device and the second electrical contact device against disconnection.

Input/output (I/O) connectors (1) for conducting data at high data rates, (e.g. 112 gigabits per second or more) are provided with protective shields (4, 5, 6) to provide increased mechanical strength and signal integrity.

The present application relates to the technical field of smart home, especially to an USB socket, a button controller and a smart home. The USB socket includes housing, a rubber core, and a set of terminals. The housing defines a cavity for fixing the rubber core. The set of terminals includes a first contact terminal and a plurality of second contact terminals, and the first contact terminal and each of the second contact terminals are arranged side by side. A front end of each of the second contact terminals is exposed on the glue core and located within the cavity. A front end of the first contact terminal is located below the front end of its adjacent second contact terminal, and thereby an elastic gape is formed there between, such that when a USB plug is plugged into the cavity, the front end of the first contact terminal is contacted with the front end of the second contact terminal pressed by the USB plug. The USB socket of the present application can enable the button controller to be in a zero standby state when being not in use, and thereby avoid power consumption loss.

A tool 202 for extracting a cable plug 112 from a socket 203 including a cable remover portion 206 which actuates and disconnects the cable plug 112 is described and claimed. Various implementations include a user statically or dynamically actuating and gripping the plug 112 and mechanically or frictionally gripping, or both, the plug 112. In one implementation, the cable remover portion 206 includes a ball detent 302 and catch tabs 320 which actuate the cable clip 208 and catch the cable head 210 so that the plug 112 is mechanically gripped. In another implementation, a translational ramp 800 is supported in the cable remover portion 206 so that a user dynamically moves the ramp 800, which actuates the cable clip 208 and the force of the ramp 800 and cable remover 206 together frictionally grips the plug 112.

A diagnostic port connector for a vehicle that includes a locking mechanism is disclosed. The system can comprise a connector body, such as a male OBD-II connector. The connector can include a plurality of connector pins, with the pins capable of passing signals and messages from the vehicle's on board diagnostic system to a device in electrical communication with the connector. The connector can also include a connection retention component. The connection retention component can be configured to maintain a connection between male connectors and female connection ports by interfering with a protruding portion of the female connection port.

The present disclosure provides a coupling system for coupling a medical accessory to an accessory support is provided. The present disclosure also provides a system for powering a medical accessory with an accessory support.