The present disclosure provides a female connector and a connector combination. The female connector is connected to a PCB board internally provided with a signal layer and a ground layer, a surface of the PCB board being provided with conductive pads connected to the signal layer and the ground layer; the female connector includes: a female terminal including a first end and a second end; the second end being provided with a plurality of differential signal pairs arranged at intervals and ground pins each located between any adjacent two of the differential signal pairs; the differential signal pairs being connectable to the signal layer through the conductive pads, and the ground pins being connectable to the ground layer through the conductive pads; a high-frequency radiation area being formed in the vicinity of a joint between the differential signal pair and the conductive pad when the first end is mated with the male connector or the gold finger circuit board; and a wave-absorbing material disposed in a spatial range covered by the high-frequency radiation area. By selectively disposing a wave-absorbing material in an area where a high-frequency radiation is easily generated during the use of the connector, crosstalk signals are absorbed, while normally transmitted electrical signals are retained, and an overall weight of the connector is light.

Self-aligning mounting systems and methods for an electrical connectors and controllers of an electrified vehicle include a dock member configured to be fixedly attached to a frame of the electrified vehicle and to at least temporarily secure the electrical controller therein and at least one floating electrical connector floatably mateable with the dock member such that the floating electrical connector is movable by a tolerance distance amount along each of at least first and second perpendicular axes that are each parallel to the base portion of the dock member, and configured to, during securement of the electrical controller within the dock member along a third axis perpendicular to the first and second axes, electrically connect a first connection portion of the floating electrical connector to a corresponding other electrical connector, such as an inline electrical connector or an electrical connector in a bottom surface of the electrical controller housing.

The present invention suggests an electrical connection device having a noise blocking and damage preventing structure by comprising: a receptacle consisting of a plurality of conductive terminals and a plurality of conductive members; and a connector comprising a plurality of connector terminals corresponding to the plurality of conductive terminals.

The present invention relates to an FPC connector housing, more particular to a DDRS connector housing. The invention also relates to a method for producing the connector housing as well as to a cavity mold suitable for the production of the connector housing. The cavity mold comprises a double gating system with centrally positioned injection gates. The connector housing can be used in a connector for mounting on a flexible printed circuit (FPC) assembled in various kinds of electrical and/or electronic devices.

An electrical connector includes a housing with a housing body and a cover mount. The housing has a cable cavity that extends through the cover mount along a connector axis. The electrical connector includes a first cover. The first cover is located on the first side of the connector axis. A second cover is located on a second side of the connector axis. The first cover engages the second cover to retain the covers in their relative positions. The covers also engage the cover mount to retain their position relative to the housing.

A spring clip has a first beam and a second beam connected to the first beam. The second beam is resiliently deflectable toward the first beam from a relaxed position distal from the first beam to a compressed position proximal to the first beam. The second beam has a spring latch disposed at an end of the second beam and extending toward the first beam. The spring latch engages the first beam to secure the second beam in the compressed position.

Provided are terminal-free connectors for flexible interconnect circuits. A connector for connecting to a flexible interconnect circuit comprises a base comprising a housing chamber defined by at least a first side wall and a second side wall that are oppositely positioned about the base. A circuit clamp is coupled to the base via a first hinge, and is configured to move between a released position and a clamped position. A cover piece is coupled to the base via a second hinge, and is configured to move between an open position and a closed position. The circuit clamp is configured to secure the flexible interconnect circuit between the base and the circuit clamp in the clamped position. One or more protrusions on the circuit clamp are each configured to interface with a socket within the first or second side wall to secure the circuit clamp in the clamped position.

The locking members have an upper arm portion that extends in the forward-backward direction, a mountable portion that is mounted to the housing downwardly of the upper arm portion, and a strut portion that extends upwardly from the mountable portion and is coupled to the upper arm portion, the upper arm portion has a pressure-receiving arm portion that extends forwardly from the top end of the strut portion and a locking arm portion that extends toward the rear from the top end of the strut portion, the locking arm portion has an engaging portion positioned so as to permit engagement with the flat-type conductor when the movable member is in the closed position, the pressure-receiving arm portion has its front end portion located downwardly of the other parts while forming a pressure receiving portion.

The locking members have an upper arm portion, a mountable portion, and a strut portion; the upper arm portion has a. pressure-receiving arm portion and a locking arm portion; the mountable portion has an upper clamping portion and a lower clamping portion that extend in the forward-backward direction, and a coupling portion that couples the upper clamping portion and the lower clamping portion, with the upper clamping portion being resiliently displaceable in the up-down direction, and the mounting portion of the housing being clamped by the upper clamping portion and lower clamping portion in the up-down direction; the strut portion extends upwardly from the upper clamping portion and is coupled to the upper arm portion; the movable member has cam portions located above the pressure-receiving arm portions; and the cam portions depress the pressure-receiving arm portions downward when the movable member moves from the closed position to the open position.

A self-aligning mechanical mount and electrical connection system for an electronic module comprises a mechanical mount assembly configured to be integrated into or attached to a base frame and defining a mount connection position assurance (CPA) feature for self-aligning and securing of the electronic module therein, and an electrical connection assembly configured to be integrated into or attached to the mechanical mount assembly and comprising a modular electrical connector (i) being electrically connected to an electrical backbone wire cable and (ii) defining a connector CPA feature for self-aligning the modular electrical connector with a corresponding electrical connector integrated into or attached to the electronic module when the electronic module is secured in the mechanical mount assembly.