A system is disclosed that is configured to secure a connection between a component and at least one wire, such as an antenna, within a computer. The system includes a retainer configured to move between a first position and a second position. The retainer in the first position is configured to secure a connection between at least one connector of the component and the at least one wire within the computer. The retainer in the second position is configured to permit release of the connection between the at least one connector of the component and the at least one wire within the computer, such as by providing access to the connection.

A connector assembly according to the present invention includes a receptacle connector; and a plug connector to be slidably inserted into the receptacle connector, wherein the plug connector includes a signal pin having one side in electrical contact with a signal line of a cable, a shield can formed to enclose the signal pin so that a lower surface of the other side of the signal pin is exposed and to be electrically spaced apart from the signal pin, a first insulating member coupled to the signal pin to insulate between the signal pin and the shield can, and a plug shell enclosing the shield can so as to expose the lower surface of the other side of the signal pin.

A conductor terminal with an insulating material housing and a spring-force terminal connection. The spring-force terminal connection has a contact body which is shaped out of a sheet element and has a base portion, lateral wall portions that protrude from the base portion and are mutually spaced, and solder connection contact tongues. The base portion together with the lateral wall portions forms a conductor receiving channel for receiving an electric conductor, and leaf spring tongues protrude from the lateral wall portions so as to face one another, each leaf spring tongue has a clamping edge for clamping an electric conductor received in the conductor receiving channel. The insulating material housing has a conductor insertion opening which leads to the conductor receiving channel on the front face.

The subject disclosure relates to a water-tight sealed stud assembly for high current applications. The water-tight sealed stud assembly can include a stud, a sealing ring, a sleeve, and a body. The stud may have a stud base and a thickened portion having an annular groove. The sealing ring may be disposed in the annular groove. The sleeve may be disposed circumferentially around the stud and made of a conductive material. The body may be disposed circumferentially around the sleeve and made of a non-conductive material. Systems and methods are also provided.

A capacitor unit (20) includes: a harness side terminal (23) provided on a first end portion (22a) side of a first surface of a housing (22) for accommodating a capacitor main body therein; a board side terminal (24) provided in the housing (22) and connectable to a circuit board; and a plurality of guide portions (25) that protrude from the first surface and extend from a second end portion (22b) on a side opposite to the first end portion (22a) toward the first end portion (22a). The plurality of guide portions (25) are provided to be separated in a second direction orthogonal to a first direction of connecting the first end portion (22a) and the second end portion (22b) to each other so as to sandwich the harness side terminal (23) therebetween.

A terminal clamp including a contact cage including a cage floor, a cage ceiling and two cage side walls that are arranged opposite to each other and respectively connect the cage floor with the cage ceiling, wherein the cage floor, the cage ceiling and the two cage side walls form an inner enveloping surface in combination and envelop a conductor receiving cavity; a clamping device formed by at least one spring element and a reaction bearing, the clamping device configured to support and electrically contact an electrical conductor in the conductor receiving cavity; a frontal conductor insertion opening that is enveloped by the two cage side walls, the cage ceiling and the cage floor, wherein the electrical conductor is insertable through the conductor insertion opening into the conductor receiving cavity and feedable to the clamping device; a contact cage longitudinal axis oriented in the conductor insertion direction.

A stacked I/O connector with surface mountable tails and a printed circuit board (PCB) configured to receive the connector. The connector may avoid terminal deformations or scratches when the connector is mounted to the PCB. The PCB may include solder pads on a single surface or both surfaces. The sold pads may be configured for the tails of the connector to be attached with a surface mount soldering technique. As a result, the connector has high density and high speed, requires, requires a smaller mounting area on a PCB, relaxes the limitations in routing PCB traces, and reduces the electrical performance deterioration caused by PCB trace routing limitations. The connector may have row-oriented terminal subassemblies, holes in the connector housing and other features to facilitate reliable manufacture and operation of the connector.

An Insulation Displacement Contact Compliant connector system (IDCC) which includes a housing, header pins, and a Printed Circuit Board (PCB). Each header pin has at least a single barb to be retained into the housing. Each pin has a blade for contacting a wire. A compliant feature on the pin retains itself into holes in the PCB. The housing has a negative space similarly shaped to the pin. The housing includes a strain relief which provides a lead-in for a wire. When the system is fully assembled, the pins reside in the housing, and exit through the housing and into and through respective holes in the PCB. A wire can be inserted into the housing once the pins reside in the housing. There are several options for the assembly process including a) a pin-to-housing insertion process; b) a housing assembly-to-PCB process or a connector-to-PCB process; and c) a wired housing assembly-to-PCB assembly process or a wire harness-to-PCB assembly process.

A terminal block assembly for a power tool comprises a terminal block having at least one primary terminal configured for electrical connection with a battery and at least one secondary terminal in electrical connection with the at least one primary terminal. A substrate is mountable on the terminal block. The substrate has at least one first electrical connector electrically connectable with the at least one secondary terminal and at least one second electrical connector in electrical connection with the at least one first electrical connector. At least one wire is electrically connected to the at least one second electrical connector. An overmold is configured to cover the at least one second electrical connector and at least a portion of the at least one wire.

A terminal clamp including a contact frame that forms a clamping device configured to fix and electrically contact a connection conductor, wherein the clamping device is formed by at least one reaction bearing and a clamping spring that is preloaded against the at least one reaction bearing; a conductor insertion channel that feeds the connection conductor to the clamping device; and an insulation material housing made that receives the contact frame and forms a conductor insertion opening that is arranged upstream of the conductor insertion channel in a conductor insertion direction, wherein the conductor insertion channel is formed by the insulation material housing.