An interposer assembly including a plate and a plurality of conductive contacts extending through plate passages for forming electrical connections with pads on overlying and underlying substrates.

A plurality of module housings extending in a lateral direction and arranged in a longitudinal direction orthogonal to the lateral direction, and terminals attached to the module housings are included. The terminals each include a pair of contact parts respectively projecting upward above an upper surface and downward below a lower surface of each of the module housings, and a first direction conversion mechanism configured to convert at least some of displacement and a force received by the pair of contact parts in an upper-lower direction orthogonal to the lateral direction and the longitudinal direction into displacement and a force in the longitudinal direction. The module housings each include a second direction conversion mechanism configured to convert at least some of displacement and a force received from each of the terminals in the longitudinal direction into displacement and a force in the upper-lower direction.

An electrical connector or electrical connector assembly that has a housing, a contact carrier, one or more spring members, and an interposer or contact system. The contact carrier is movable with respect to the housing between unmated and mated electrical positions.

A connecting structure includes at least one conductive terminal having a body, a conducting portion connected below the body, a pre-breaking portion provided at an upper end of the body, and a temporary soldering portion connected above the pre-breaking portion; a first strip connected to the conducting portion; and a second strip soldered to the temporary soldering portion. A method for manufacturing an electrical connector includes: forming a first strip and at least one conductive terminal connected thereto; soldering a second strip to the temporary soldering portion of the conductive terminal; separating the conducting portion of the conductive terminal and the first strip; operating the second strip to control the conductive terminal to be mounted to a housing; and disconnecting the pre-breaking portion of the conductive terminal, and removing the second strip and the temporary soldering portion of the conductive terminal.

An electrical connector includes an insulating body. At least one accommodating hole runs through the insulating body vertically, and each accommodating hole has a stopping portion and a position limiting portion. Each accommodating hole accommodates a terminal and an electrical conductor. The terminal is in contact with the electrical conductor. The terminal upward abuts the stopping portion. The terminal is connected to a first strip downward, and is mounted into the accommodating hole upward from bottom. The electrical conductor upward abuts the position limiting portion. The electrical conductor is connected to a second strip downward, and is mounted into the accommodating hole upward from bottom. The terminal upward abuts the stopping portion and thus does not excessively move upward, and the electrical conductor upward abuts the position limiting portion and thus does not excessively move upward.

An interposer includes a housing and a contact disposed in the housing. The housing has a first face, a second face opposite the first face, and a passageway penetrating the first face and the second face. The contact has a base portion press-fitted in the passageway, a first contact beam extending obliquely with respect to the first face from the base portion, and a second contact beam extending obliquely with respect to the second face from the base portion. The first contact beam extends outward beyond the first face and has a first contact point portion. The second contact beam extends outward beyond the second face and has a second contact point portion. The first contact point portion and the second contact point portion both extend beyond a penetrated region of the passageway in a direction perpendicular to an insertion direction in which the contact is inserted into the passageway.

A test socket (14) for a testing an integrated circuit (12) with controlled impedance while maintaining the structural integrity of the test pins (20). The pin (20) can have a sidewall with a thick portion 32 and a thinner portion (30) along the length of the pin. The pin can have projections (42) which provide a standoff from the slot (40). The sidewalls themselves can have projections or lands (60, 61) which extend into the slot and provide stability for the pin (20).

An electrical contact includes a main body, a supporting arm extending upwardly from an upper edge thereof, and a spring arm extending curvedly and upwardly from a lower edge thereof with a contacting region at a free end. The spring arm will contact the supporting arm when the spring arm is downwardly pressed by the CPU. A solder part is sidewardly connected to a downward extension formed on a lower portion of the main body and located beside the spring arm, and includes a vertical section extending from the side edge of the downward extension, a horizontal solder pad extending from a lower edge of the vertical direction wherein a curved joint is formed between the downward extension and the vertical section for easy adjusting the angle formed between the downward extension and the vertical section, thus being adapted to fit different CPUs and PCBs.

An electrical connector includes an insulative housing and a contact module essentially composed of a plurality of contacts integrally formed within an insulator via an insert-molding process wherein the contact module is assembled to the housing via two steps along different directions perpendicular to each other. The housing forms a plurality of protrusions engaged with the corresponding ribs of contact module in the vertical direction so as to retain the contact module to the housing reliably. All the insulator, the contacts and the housing are arranged in a staggered manner.

A shielded interconnect array and associated methods are described. Examples of the shielded interconnect array include socket connections that include conductive members with flexible bends. In examples shown, corresponding grounded conductive members with flexible bends are located adjacent to other conductive members with flexible bends to provide shielding.