An apparatus for grounding a heatsink utilizing an EMC spring press-fit pin includes a printed circuit board, a logic chip, a heatsink, and a grounding member, where the grounding member includes an integrated spring and a first terminal pin at a first end of the grounding member. The logic chip is electrically coupled to the printed circuit board and the heatsink is disposed on a top surface of the logic chip. The first terminal pin at the first end of the grounding member is disposed in a plated-through hole of the printed circuit, where the grounding member is configured to electrically couple the heatsink to the printed circuit board.

An apparatus for grounding a heatsink utilizing an EMC spring press-fit pin includes a printed circuit board, a logic chip, a heatsink, and a grounding member, where the grounding member includes an integrated spring and a first terminal pin at a first end of the grounding member. The logic chip is electrically coupled to the printed circuit board and the heatsink is disposed on a top surface of the logic chip. The first terminal pin at the first end of the grounding member is disposed in a plated-through hole of the printed circuit, where the grounding member is configured to electrically couple the heatsink to the printed circuit board.

A contact assembly for an electrical connector includes a contact positioner having contact support walls holding a contact array. The contact array includes signal contacts and ground contacts interspersed with the signal contacts. The signal contacts include mating ends configured to be mated with a mating electrical connector and mounting ends configured to be terminated to a host circuit board. The signal contacts include transition portions between the mating ends and the mounting ends. The ground contacts include mating ends, mounting ends, and transition portions between the mating ends and the mounting ends. The contract assembly includes a ground bus wire extending transversely across the contact array. The ground bus wire is electrically connected to each of the ground contacts. The ground bus wire is electrically isolated from each of the signal contacts.

A first sheet metal is provided with slits. Elastic pieces having flat shapes are each formed between the slits adjacent to each other, and both ends of each of the elastic pieces are connected with both ends of an adjacent one of the elastic pieces. A second sheet metal is provided with protrusions each of which is protruded toward a corresponding one of the elastic pieces.

An electrical connector grounding structure includes an electrically insulative terminal holder block having a rectangular base, a mating structure and a fixing structure, conducting terminals positioned in the rectangular base with contact tips thereof extended to the mating structure and connection tips thereof bonded to a predetermined circuit board, a grounding member having a first contact structure, a positioning structure positioned in the fixing structure and a bonding structure bonded to the circuit board, and a shielding shell covering the electrically insulative terminal holder block and having a second contact structure set in contact with the first contact structure to form a ground loop that guides out electromagnetic waves and crosstalk interference generated during signal transmission.

A contact assembly for an electrical connector includes a contact positioner having contact support walls holding a contact array. The contact array includes signal contacts and ground contacts interspersed with the signal contacts. The signal contacts include mating ends configured to be mated with a mating electrical connector and mounting ends configured to be terminated to a host circuit board. The signal contacts include transition portions between the mating ends and the mounting ends. The ground contacts include mating ends, mounting ends, and transition portions between the mating ends and the mounting ends. The contract assembly includes a ground bus wire extending transversely across the contact array. The ground bus wire is electrically connected to each of the ground contacts. The ground bus wire is electrically isolated from each of the signal contacts.

A connector-equipped multicore cable includes a connector including a first end portion and a second end portion and a multicore cable including a plurality of coaxial electrical wires and connected to the first end portion. The connector includes, at the second end portion, a cover that is made of a metal and that covers a connector terminal. The plurality of coaxial electrical wires each include a first shield layer. The first shield layer and the cover are electrically connected to each other.

Systems for optimizing mounting points for coaxial RF connectors, including a printed circuit board (PCB) comprising a coaxial radio frequency (RF) connector; a faceplate comprising an opening adapted to receive the coaxial RF connector; and a bushing positioned within the opening, wherein the coaxial RF connector is positioned within the bushing.

Systems for optimizing mounting points for coaxial RF connectors, including a printed circuit board (PCB) comprising a coaxial radio frequency (RF) connector; a faceplate comprising an opening adapted to receive the coaxial RF connector; and a bushing positioned within the opening, wherein the coaxial RF connector is positioned within the bushing.

A connector assembly includes a metal shielding cage. The metal shielding cage includes a cage body, a back cover and a grounding member. The cage body has a top wall, a mounting side and two side walls, the top wall, the mounting side and the two side walls together define a receiving space extending along a front-rear direction, the receiving space has a front opening toward the front and a rear opening positioned at the rear, the back cover and the grounding member are assembled at the rear opening of the cage body, and the grounding member is provided with an elastic grounding finger row toward the mounting side.