An electrical connector includes a housing formed of a fixed housing and a movable housing movable relative to the fixed housing. The connector further includes a terminal. The terminal includes a connecting portion to be connected to the electrical circuit board and a contact portion to be contacted with the mating connecting member. The terminal further includes a fixed side held portion, a movable side held portion, and an elastic portion. The connecting structure further includes a regulating portion for regulating the elastic portion from elastically deforming within a specific elastic deformation range. The elastic portion is configured to have a specific elastic deformation range. When the electrical connector is connected to the mating connecting member, the spring force is smaller than a holding force between the contact portion of the terminal and the mating connecting member in a direction that the electrical connector is pulled out.

A computer system assembly that includes a substrate and a first board mounted on the substrate. A flexible cable is secured to the first board. The computer system assembly further includes a second board mounted on the substrate. The second board includes a FPC connector. The FPC connector includes a body having a channel extending through the body such that the flexible cable may be positioned in the channel and pulled entirely through the body of the FPC connector. The FPC connector further includes a latching mechanism that secures the flexible cable within the channel once the flexible cable is pulled through the FPC connector. The first board and the second board are moved closer together as the flex cable is pulled through the FPC connector before at least one of the first board and the second board is mounted on the substrate.

In one implementation, a system for a tool-less multipoint latching mechanism includes a number of adjustable cams of a bracket to interact with a number of corresponding cam surfaces located on a computing board, a number of locking locations to couple a printed circuit assembly (PCA) to the bracket, and a number of pin-in-slot joints of the bracket that interact with the number of adjustable cams to vertically lower the coupled PCA into a number of receiving connectors on the computing board.

The present invention relates to an actuator that has a specific structure, and is molded from a resin composition, in which the resin composition contains a liquid crystal polyester having a specific repeating unit and a filling material, an amount of the repeating unit including a 2,6-naphthylene group is 40 mol % or more with respect to a total number of moles of all repeating units configuring the liquid crystal polyester, and an amount of the filling material is less than 55 parts by mass with respect to 100 parts by mass of the total amount of the liquid crystal polyester and the filling material.

An electronic device including a body and a female connector is disclosed. The Body has an opening and a positioning structure disposed corresponding to the opening. The female connector is disposed in the body corresponding to the opening and is pivotally connected to the positioning structure. A male connector is adapted to pass through the opening and plugged into the female connector, and the female connector is adapted to be driven by the male connector to rotate around a rotation axis passing through the positioning structure.

This invention describes an improved contact termination interface assembly between pins or male contacts and via holes in PCBs or backplanes or simple sockets or female contacts. This invention permits to achieve reliable electromechanical connection between a connector directly with a PCB thereby eliminating the need for a second mating connector to be installed on the PCB. This invention offers an alternative to mounting connectors to PCBs other than through-hole solder or press-fit technology. This invention allows a unibody connector to connect a daughter board directly to a mother board either in parallel or right-angle orientation. One embodiment of this invention allows for a connector to achieve multiple blind-mating cycles with a backplane using a self-guiding, self-retractive, contact protection face, which applies pressure on all contacts once inserted into the backplane to achieve reliable electromechanical connection. Other embodiments of this invention permit male contacts to mate directly with metallized via holes, tube sockets or female contacts without any additional retention or pressure elements required to create the electromechanical connection. Other embodiments allow to reach a fully mated condition between the mating counterparts with zero insertion force because the offsetting pressure between the contacts is applied after the mating of the counterparts.

The connector has a housing and a retainer. The retainer is accommodated in the housing and has a base portion and a front upper beam extending forward from the base portion and positioned above an insertion passage of a flat cable. The upper beam includes a middle portion positioned in the middle of the upper beam and a forward extending portion extending forward from the middle portion. The middle portion has an engaging portion configured to engage an engaged portion of the cable, and at least a portion is positioned in the passage of the cable. A region is provided in the leading end of the extending portion above the leading end of the extending portion for restricting upward movement. The upper beam is elastically deformable so that the middle portion moves upward when the upward movement of the leading end of the extending portion is restricted by the region.

A card connector assembly includes: an electrical connector for being mounted behind an opening in a housing of an electronic device, the electrical connector including a cam groove, a slider, a biasing member, and a cam bar coupled between the cam groove and the slider; and a card tray insertable into the electrical connector through the housing opening for moving the slider from the ejected position to the inserted position; wherein the cam bar has a push portion; the card tray includes a latch, the latch being adapted to be stopped by the electronic device housing when the slider is at the inserted position; and when pushing the card tray to move the slider from the inserted position to the ejected position, the push portion of the cam bar releases the latch for the slider together with the card tray to move to the ejected position.

An electrical connector has at least one latch that is rotatable on the connector body to allow a module board to be clamped between an upper clamp surface of the latch and a lower clamp surface of the connector body. The electrical connector has connector pins having contact points within an opening of the connector body. When a module board is inserted into the opening, the contact points are pushed from a first height elevation to a second height elevation, which is level with the lower clamp surface.

The connector has a housing and a retainer. The retainer is accommodated in the housing and has a base portion and a front upper beam extending forward from the base portion and positioned above an insertion passage of a flat cable. The upper beam includes a middle portion positioned in the middle of the upper beam and a forward extending portion extending forward from the middle portion. The middle portion has an engaging portion configured to engage an engaged portion of the cable, and at least a portion is positioned in the passage of the cable. A region is provided in the leading end of the extending portion above the leading end of the extending portion for restricting upward movement. The upper beam is elastically deformable so that the middle portion moves upward when the upward movement of the leading end of the extending portion is restricted by the region.