A high-performance single barrel power connector for receiving electric power may be capable of receiving more than 330 W up to approximately 600 W of power. The V+ pin and V− pin may each be configured with a large plurality of contact points for connecting to a power plug. A connector body retaining the V+ pin and V− pin may configured with openings to expose more of the V+ pin and V− pin to air and allow the V+ pin and V− pin to extend out of the power connector for convective and conductive heat transfer. A shell having a high thermal conductivity may be connected to the V− pin and V− pin and further connected to a bracket for increased heat transfer away from the V+ and V− pins.

There is provided a coaxial connector that can suitably bias a movable insulator to the side of a socket and maintain matched impedance. The coaxial connector includes a movable insulator that is fitted in a central conductor so as to be slidable and is housed in an insulator housing so as to be movable in an axial direction; and a biasing rubber member that is interposed between a partition disposed in the recesses of the insulator housing and the movable insulator. When the biasing rubber member connects the socket to the plug, the movable insulator is pushed in by a pushing force from a socket, and elastic pillars are bent in an arc shape.

An electrical connector including an electrically conductive shell sized to receive and retain an electrically insulating housing insert, where the housing insert includes a cavity for receiving and retaining a wire-terminating electrical contact therein. The shell and housing insert each including keying features designed to cooperate with one another to resist independent rotation of the housing insert within the shell. The electrical connector further includes a wire sealing grommet coupled to the housing insert to improve connector performance and minimize arcing issues.

A dual cable alignment apparatus (10) for rotationally aligning assembled cable ends of two cables (3,4) of a twisted cable harness (2), the cable alignment apparatus (10) comprising two clamping jaws (7,8) and a central web (9) disposed between the clamping jaws (7,8). Each of the two clamping jaws (7,8), which can be moved towards one another in the closing direction (s), can clamp a cable (3,4) between the central web (9) and the clamping jaws (7,8). The clamping jaws (7,8) are further designed to be movable laterally past the central web (9) for changing the rotational position by rolling the cable (3,4) clamped between them. The clamping jaws (7,8) can be moved independently of one another in the lateral direction by means of their own lateral drives (16,17), ensuring that each cable (3,4) can be brought precisely and reliably into the desired rotational position.

A connection element is disclosed. In an embodiment, the connection element includes a guide element and first and second contact elements arranged at a distance from one another. The guide element at least partially surrounds the contact elements and is configured to guide and receive at least one mating connection element. The first and second contact elements have respective first and second contact sections configured for connection to a mating contact element of the mating connection element. The first and second contact sections lie on a straight connecting line which runs orthogonally through the first and second contact element axes and the contact sections have different lengths along a direction of the straight connecting line. A kit of parts and an electronic component part, each including at least one connection element as described, are also disclosed.

An electrical receptacle contains a plug outlet that has a pair of contacts for electrical connection to respective hot and neutral power lines. A controlled switch, such as a TRIAC, is connected in series relationship between the outlet contact and the hot power line. Sensors in the receptacle outputs signals to a processor having an output coupled to the control terminal of the controlled switch. The processor outputs an activation signal or a deactivation signal to the controlled switch in response to received sensor signals that are indicative of conditions relative to the first and second contacts.

An electrical outlet may be stored (e.g., stocked at a manufacturer and/or a warehouse) in a bulk form and may be constructed to have a desired color, finish, and/or material prior to shipment to a customer. The outlet may comprise a rear bezel portion having a front surface with openings configured to receive blades of a plug of an electrical device for electrically connecting the electrical device to a power source and a front bezel portion configured to be mounted over the rear bezel portion. The rear bezel portion may have openings aligned with the respective openings of the rear bezel portion for receiving the blades of the plug. In addition, the electrical outlet may have a temporary bezel when stocked at the manufacturer and/or the warehouse. The temporary bezel may be removed from the outlet and a permanent bezel may be installed on the outlet prior to shipment.

A multi-position conversion device and a conversion socket with the multi-position conversion device; the first pin, the second pin, the first connecting sheet and the second connecting sheet are installed together onto the main frame to modularize and integrate the conversion device; therefore, only one main frame is needed to complete the installation of the first pin, the second pin, the first connecting sheet and the second connecting sheet, and this can effectively decrease the volume of the multi-position conversion device and thus decrease the volume and weight of the whole conversion socket, prevent the conversion socket from sagging due to gravity and thus increase the corresponding user experience and safety; meanwhile, after being modularized, the multi-position conversion device is installed directly into the housing and thus can decrease the assembling steps, reduce the assembling difficulty and finally improve the assembling efficiency.

A connecter terminal structure includes: a male housing of a male connecter; a male terminal accommodated in the male housing and including a first electrical contact portion; a stepped shaft portion formed at a tip end of the first electrical contact portion; a hood portion surrounding the first electrical contact portion; an annular terminal spring externally fitted to the stepped shaft portion; and an insulating cap fixed to a tip end of the stepped shaft portion and configured to hold the annular terminal spring. The connecter terminal structure further includes: a female housing of a female connecter; a female terminal accommodating portion configured to be fitted into the hood portion; and a female terminal accommodated in the female terminal accommodating portion and including a second electrical contact portion having a tubular shape to allow the first electrical contact portion to be inserted therein.

A method of assembling a water-in-fuel sensor assembly. The method includes an initial step of providing a housing that has a recess, at least one pin located within the housing, a circuit board, and at least one terminal configured for engaging the at least one pin. The method also includes forming a board-mounting subassembly by coupling the at least one terminal to the circuit board. The method also includes positioning the board-mounting subassembly within the housing by engaging the at least one terminal with the at least one pin such that the board-mounting subassembly is disposed within the recess of the housing.