Interposer printed circuit boards for power modules and associated methods are disclosed. In at least one illustrative embodiment, a printed circuit board assembly may comprise a printed circuit board having a surface, an electrical component mounted on the surface, a pin mounted on the surface, and an interposer printed circuit board mounted on the surface. The electrical component may have a first height orthogonal to the surface. The pin may have a second height orthogonal to the surface, where the second height is greater than the first height. The interposer printed circuit board may comprise a pad and an outer solder bump positioned on the pad. The outer solder bump may have a third height orthogonal to the surface, where the third height is greater than the first height.

Interposer printed circuit boards for power modules and associated methods are disclosed. In at least one illustrative embodiment, a printed circuit board assembly may comprise a printed circuit board having a surface, an electrical component mounted on the surface, a pin mounted on the surface, and an interposer printed circuit board mounted on the surface. The electrical component may have a first height orthogonal to the surface. The pin may have a second height orthogonal to the surface, where the second height is greater than the first height. The interposer printed circuit board may comprise a pad and an outer solder bump positioned on the pad. The outer solder bump may be positioned at a third height orthogonal to the surface, where the third height is greater than the first height.

An independent loading mechanism for use with a CPU connector includes a metallic frame cooperating with a back plate module to sandwich a printed circuit board therebetween. A plurality of screw nut units are provided around the four corners of the frame. A plurality of hollow spacers are secured to the corresponding through holes of the frame so as to allow the corresponding screw nut units moveable relative to the frame along the vertical direction within a range larger than a thickness of the frame, thus avoiding improper interference between the screw nut units and the corresponding screw posts of the back plate module during sequential screwing.

Aspects of the invention include an apparatus to aid a surface mount connection process including a barrier, a substrate in a facing spaced relationship with the barrier, a hybrid land grid array (LGA) socket interposed between the barrier and the substrate, and at least one fastening mechanism securing the barrier to the substrate at a selected distance such that a gap is formed between the barrier and the hybrid LGA socket.

An electrical connector comprises a plurality of substrates, a first plurality of spacers, a second plurality of spacers, a plurality of pitch transformation routing assemblies, and a plurality of contact assemblies. The plurality of substrates each extends along a first direction. Each of the second plurality of spacers and a respective spacer of the first plurality of spacers connect a respective substrate of the plurality of substrates to a respective adjacent substrate of the plurality of substrates. Each of the plurality of pitch transformation routing assemblies is surrounded by a corresponding substrate of the plurality of substrates, a corresponding spacer of the first plurality of spacers, a corresponding adjacent substrate of the plurality of substrates, and a corresponding spacer of the second plurality of spacers.

An integrated circuit (IC) socket comprising a housing with a land side, an opposing die side, and sidewalls around a perimeter of the housing. The housing comprises a first dielectric. A plurality of socket pins extends from the land side of the housing through socket pin holes in the housing over the die side of the housing. A second dielectric is within the interstitial regions between the socket pins and sidewalls of the socket pin holes. A frame structure extends around at least a portion of the perimeter of the housing, and a mesh structure is embedded within the first dielectric. The mesh structure has plurality of mesh filaments extending between the plurality of socket pin holes and coupled to the frame structure.

The electrical connector is equipped with a retention mechanism for securing mounting a heat sink upon a CPU which is received within an insulative housing of the connector. The retention mechanism includes a pair of seats, a pair of towers fixed to the pair of seats, respectively, a pressing device retained between the pair of towers in a deformable manner. The pressing device is intimately seated upon the heat sink to significantly press the heat sink against the CPU when the pressing device is deformed in a tensional status.

An electrical connector comprises a plurality of substrates, a first plurality of spacers, a second plurality of spacers, a plurality of pitch transformation routing assemblies, and a plurality of contact assemblies. The plurality of substrates each extends along a first direction. Each of the second plurality of spacers and a respective spacer of the first plurality of spacers connect a respective substrate of the plurality of substrates to a respective adjacent substrate of the plurality of substrates. Each of the plurality of pitch transformation routing assemblies is surrounded by a corresponding substrate of the plurality of substrates, a corresponding spacer of the first plurality of spacers, a corresponding adjacent substrate of the plurality of substrates, and a corresponding spacer of the second plurality of spacers.

An electrical connection device and a chip module connection device are disclosed. The electrical connection device includes: an insulating body, provided with multiple accommodating holes; multiple terminals, correspondingly accommodated in the accommodating holes; and multiple solder balls. Each accommodating hole is provided with a stopping portion. Each terminal has two arm portions and a stopping block located lower than the two arm portions, and the stopping block is formed by tearing downward from the accommodating groove. An accommodating groove is formed between the two arm portions and is located higher than the stopping block. The stopping portion is located on an upward moving path of the stopping block. A gap is formed between the stopping block and the stopping portion. The solder balls are correspondingly accommodated in the accommodating grooves of the terminals.

An electrical connector includes an insulative housing retaining a plurality of contacts therein and surrounded by a metallic seat. A clip includes a frame with corresponding four walls to commonly form a receiving cavity to receive the electronic package therein, and each wall forms a pressing section to downwardly press an upward surface of the electronic package. A pair of latches are formed on a lower side of the frame to cooperate with the pressing sections of the walls to retain electronic package within the receiving cavity to be wholly a sub-assembly for being commonly received within the electrical connector. The clip includes a releasing handle to actuate the corresponding latch, and the releasing handle is positioned in an opening of the seat and intimately above the printed circuit board to function as a foolproof mechanism for loading the electronic package in a right orientation.