A connector, with which an electrical wire is attachable, is connectable with a mating connector which has a mating contact portion. The connector comprises a housing and at least one terminal. The housing is provided with a support. The support has a receiving portion. The receiving portion is configured to receive a part of the electrical wire. The at least one terminal has an insulation displacement connection (IDC) portion, a contact portion, a supporting portion and a coupling portion. The IDC portion is configured to be insulation-displacement connected with the electrical wire. The support is positioned between the IDC portion and the supporting portion in a first predetermined direction. The coupling portion couples the IDC portion and the supporting portion with each other. The coupling portion has a neighboring portion. The neighboring portion neighbors to the support in a second predetermined direction perpendicular to the first predetermined direction.

A Peripheral Component Interconnect Express/Serial Attached SCSI (PSAS) female connector includes a frame member, a terminal member, and a cover member; the frame member including a terminal groove disposed in the frame member and a tilt portion disposed in the terminal groove adjacent to a plug end; the terminal member inserted in the frame member and including a Serial Advanced Technology Attachment (SATA) 7 pin terminal, a Serial Attached SCSI (SAS) 40 pin terminal, a 15 Pin signal terminal, a 6 Pin terminal, and a 4 Pin terminal. When the PSAS female connector is engaged with the male connector, the SATA 7 Pin terminal and the SAS 40 Pin terminal are pressed by a terminal of the male connector to be bent toward an outer lateral side of the terminal groove to contact the elastic plate of the cover member. The present invention effectively improves the cross interference during high speed transmission, thereby achieving the Generation 5 performance requirement.

A connector includes a contact retained in a housing selectively in one of a first posture and a second posture inverted 180 degrees around a fitting direction, the contact including a contact portion to be contacted with a contact of a counter connector and a connection portion to be connected to a flexible conductor of a connection object, between a case where the contact is retained in the housing in the first posture and a case where the contact is retained in the housing in the second posture, the contact portion is situated at a same position with respect to the housing and the connection portion is situated at a different position with respect to the housing, the contact being retained in the housing in, of the first posture and the second posture, a posture corresponding to an orientation of a flexible conductor exposed surface of the connection object.

An electrical connector having a main support with a front and back, top and bottom, and left and right opposite the left. Fingers extend forwardly from the front of the main support to a tip. The fingers each have a top and bottom and are arranged from left to right of the main support with gaps defined between them. A flexible circuit board has inner and outer surfaces with electrical leads on the outer surface. Openings are defined through the flexible circuit board between the electrical leads. The flexible circuit board is wrapped around the fingers such that the outer surface of the flexible circuit board is supported on both the top and the bottom of the fingers and the openings in the flexible circuit board are aligned with the gaps between the fingers.

Electrical connector systems and methods create an electrical connection between a flexible circuit (FC) and a metal terminal of another connector. A reliable electrical connection is achieved with a low-cost tin contact plating, by an automatic FC to metal terminal wiping action with contact force, during the connector to FC assembly process. The connector to FC assembly process is also well suited for automated robotic assembly, which can save costs compared to manual assembly/installation.

According to an embodiment, it is possible to provide an electronic device including: a housing; a first printed circuit board disposed in the housing; a second printed circuit board disposed in the housing and spaced apart from the first printed circuit board; a first flexible printed circuit board electrically connecting the first printed circuit board and the second printed circuit board; and a second flexible printed circuit board electrically connecting the first printed circuit board and the second printed circuit board, in which the second flexible printed circuit board may be longer than the first flexible printed circuit board. Other embodiments are also disclosed.

A connector has a casing and a circuit board structure. The circuit board structure is mounted through the casing and has a board main body, a projecting body, and multiple metal electrodes. The projecting body is mounted on a connecting end surface of the board main body and projects from the connecting end surface in an insertion direction of the connector. When the connector is connected to another device, the projecting body of the circuit board structure may push a part of pins of the device first, so the user may exert less force to insert the projecting body into the device. Then, when the circuit board structure is inserted further, the board main body may abut the remaining pins. Because part of the pins have been pushed away by the projecting body, the board main body only needs to counteract resistance from the remaining pins.

A connector for connecting a flexible interconnect circuit comprises a base comprising a first set of protrusions and a second set of protrusions. The first set of protrusions and second set of protrusions are configured to secure the flexible interconnect circuit at a first set of apertures and a second set of apertures of the flexible interconnect circuit, respectively. The first set of protrusions may be positioned at a first distance from the second set of protrusions on the base. The first set of apertures may be positioned on the flexible interconnect circuit at a second distance, greater than the first distance, from the second set of apertures. The base causes the flexible interconnect circuit into an arched configuration when the apertures are secured to the respective protrusions. The connector further comprises a cover piece configured to secure the flexible interconnect circuit in the arched configuration.

Described herein are circuit assemblies comprising flexible interconnect circuits and/or other components connected to these circuits. In some examples, conductive elements of different circuits are connected with support structures, such as rivets. Furthermore, conductive elements of the same circuit can be interconnected. In some examples, a conductive element of a circuit is connected to a printed circuit board (or other devices) using a conductor-joining structure. Interconnecting different circuits involves stacking these circuits such that the conductive element in one circuit overlaps with the conductive element in another circuit. A support structure protrudes through both conductive elements and any other components positioned in between, such as dielectric and/or adhesive layers. This structure electrically connects the conductive elements and also compresses the conductive elements toward each other. For example, a rivet is used with the rivet heads contacting one or two conductive elements, e.g., directly interfacing their outer-facing sides.

Embodiments disclosed herein include sockets and electronic packages with socket architectures. In an embodiment, a socket comprises a housing with a first surface and a second surface. In an embodiment, a plurality of interconnect pins pass through the housing. In an embodiment, an alignment hole is provided through the housing. In an embodiment, an alignment post extending out from the first surface of the housing is also provided.