A chip carrier for carrying an electronic chip, wherein the chip carrier comprises a mounting section configured for mounting an electronic chip by sintering, and an encapsulation section configured for being encapsulated by an encapsulant.

An electronic component includes a first module, a second module and a third module between the first module and the second module. Each of the first module and the second module includes a plurality of conductive pads thereon. A connecting part includes a plate body and a plurality of first tails and a plurality of second tails respectively extending on two opposite sides of the plate body wherein the first tails are soldered upon the first conductive pads and the second tails are soldered upon the second conductive pads, respectively. Each of the first tails and the second tails includes a mounting pad with a through hole therein, and a folded section on the end edge with a solder unit received with a space formed in the folded section and communicatively above the corresponding through hole.

An electrical connector includes a fastener plate, a rail frame pivotally mounted to one end of the fastener plate, a carrier frame assembled to the rail frame in a sliding manner, and a load plate pivotally mounted to the end of the fastener plate outside of the rail frame. The carrier frame includes latches to retain the CPU thereon. The rail frame includes a pair of opposite sliding channels extending in the front-to-back direction, along which the carrier frame is moveable. A front transverse bar is located in front of the sliding channels. A pair of protection blocks are located in front of the pair of sliding channels for protecting the latches of the carrier frame or the CPU.

A module installation assembly for installing a module into a socket of a land grid array includes a tool having a mounting bracket for connecting the tool to an adjacent fixture, an alignment member connected to the mounting bracket, and cavity defined at least partially by the alignment member. The cavity is substantially aligned with a socket of the land grid array such that the module is configured to pass through the cavity when being connected to the socket.

When each signal line contact terminal (10ai) is installed in a base member (30), an upper housing (28), and a lower housing (26), the upper housing (28) is installed together in such a way as to be sandwiched between the base member (30) and the lower housing (26). Here, collars (16) are fitted on outer peripheral portions of a first extending portion (52A) and a second extending portion (52C) of the signal line contact terminal (10ai), respectively. Moreover, air layers are formed between an outer peripheral portion of a drum portion (52B) of the signal line contact terminal (10ai) and an inner peripheral surface forming a hole (28b), between an outer peripheral portion of the first extending portion (52A) and an inner peripheral surface forming a hole (30b), between an outer peripheral portion of the second extending portion (52C) and an inner peripheral surface forming a hole (26b), and between an outer peripheral portion of a plunger (56) and an inner peripheral surface forming a hole (26e).

The present disclosure provides a reverse clamping compression device for CPO or NPO. The device includes a mechanical bolster placed on a main board, a compression cover covering optical modules, and a fastening connecting and fixing the compression cover to the mechanical bolster and protruding below the mechanical bolster. In the present disclosure, the compression cover above the optical modules is used to apply a compression force to the optical modules, and the spring element is placed in space below the main board, therefore, the space above the compression cover is not occupied, which can maximize the use of the space above the optical modules, greatly shorten the heat conduct path of the heat sink module, and ensure that the entire device is still assembled from top to bottom.

A connector includes an insulative housing, a plurality of contacts retained in the housing, and a metallic stiffener surrounding the housing. A first pivot section and a second pivot section respectively located at opposite rear and front ends of the stiffener. A first lever is pivotally mounted upon the first pivot section and a second lever is pivotally mounted upon the second pivot section. The first lever includes a first pivot mounted upon the first pivot section, and a first handle moveable between a closed position and an open position. The first pivot includes an offset section on which a load plate is pivotally mounted. The first pivot section includes a stopper limiting outward rotation of both the first lever and the load plate at more than ninety degrees so as not to hinder loading/unloading the CPU with regard to the housing in the vertical direction.

An electrical connector includes a stiffener, a rail frame pivotally mounted to one end of the stiffener, a carrier frame assembled to the rail frame in a sliding manner, and a load plate pivotally mounted to the end of the stiffener outside of the rail frame. The carrier frame includes latches to retain the CPU thereon. The rail frame includes a pair of opposite sliding channels extending in the front-to-back direction, along which the carrier frame is moveable. A front transverse bar is located in front of the sliding channels and above the sliding channels in the vertical direction.

A microprocessor loading mechanism, comprising a bolster plate surrounding an aperture, wherein the opening is to receive a microprocessor socket, one or more torsion bars coupled to the bolster plate, and a stud coupled to each of the one or more torsion bars, wherein each stud is to receive a nut to secure a microprocessor package to the microprocessor socket within the aperture and wherein each stud is secured to the bolster plate by each corresponding torsion bar.

Various apparatus and methods of electrically connecting a packaged integrated circuit to a circuit board are disclosed. In one aspect, an apparatus includes a first frame to be mounted on the circuit board and having a first end. An insulating housing is adapted to be mounted on the circuit board and positioned in the first frame. A second frame is pivotally coupled to the first frame. The second frame includes two spaced-apart rail members and a cross member coupled to and between the rail members opposite the first end of the second frame. The rail members are operable to receive the packaged integrated circuit. The second frame has at least one engagement member to engage a first portion of the insulating housing when the second frame is pivoted toward the insulating housing. A third frame is pivotally coupled to the first frame to apply force to the packaged integrated circuit.