In a connector, a contact includes: a first connection portion and a second connection portion that are retained between a first insulator and a second insulator and face each other; and a pressing force receiving portion that makes contact with the second insulator and receives a pressing force from the second insulator to thereby press the first connection portion against the second connection portion. A connection object is sandwiched between the first connection portion and the second connection portion, and at least one of the first connection portion and the second connection portion makes contact with a flexible conductor of the connection object, whereby the contact is electrically connected to the flexible conductor of the connection object.

A plug connector used to mate with the socket connector includes: a housing; a printed circuit board received in the housing, the circuit print board having plural soldering points; and a cable electrically connected to the soldering points of the printed circuit board, wherein the soldering points are provided with glue blocks to protect a connection between the printed circuit board and the cable.

A connector for receiving a ribbon cable is provided. The connector includes a housing with an open top, and a cable organizer configured to be positioned within an interior of the housing and the open top and to receive the ribbon cable. The cable organizer includes a surface with a first cable grab hook adjacent a first end thereof, configured to receive a first portion of the ribbon cable via a snap-fit engagement. The connector also includes cover configured to selectively cover the open top of the housing to enclose the cable organizer within the interior of the housing. The cover includes a notch extending therethrough, sized to receive an upper detent of the cable organizer so that the upper detent extends through the notch and remains viewable when the cover encloses the cable organizer within the interior of the housing.

A high-speed transmission cable and a cable end connector including the same are provided. The cable end connector includes a connector body and the high-speed transmission cable that includes at least one cable assembly, at least one transmission line, and an insulating material. The at least one cable assembly includes multiple ground wires and multiple differential pairs that are arranged at fixed intervals and in parallel with each other, an insulating layer, and at least one shielding layer. Each of the differential pairs includes two signal wires that are adjacently arranged, and is located between two adjacent ones of the ground wires. The insulating layer covers the ground wires and the differential pairs. The at least one shielding layer is located at an outer side of the insulating layer. The insulating material covers the at least one cable assembly and the at least one transmission line.

A cable housing for a flat flexible cable includes a first cable housing having a first orientation guide and a second cable housing having a second orientation opening. A plurality of flat conductors exposed in a window extending through an insulation material of the flat flexible cable are disposed between the first cable housing and the second cable housing. The first orientation guide abuts a pair of flat conductors of the plurality of flat conductors and rotates a rotated portion of each of the flat conductors to a rotated orientation when the first orientation guide moves into the second orientation opening and the first cable housing is in a mated position with the second cable housing. The rotated orientation of the rotated portion is disposed at an angle with respect to a planar portion of each of the flat conductors in the insulation material.

Described embodiments provide a flat conductive fluid sensor cable capable of manufacture in long lengths comprising a flexible substrate, two or more flat conductors, and a fluid-permeable cover material arranged to allow a conductive fluid to form an electrically conductive path between the two or more conductors when conductive fluid contacts the conductive fluid sensor cable.

A connector includes: a terminal fitting; a housing including a smooth terminal lead-out area where a terminal outlet for projecting a conductor connection part of the terminal fitting on the inner side toward an outer side is provided; a conductive component shaped in a sheet-like form with a conductor and an insulator exhibiting flexibility, the conductive component including a conductor connection area that physically and electrically connects the conductor to the conductor connection part, and a conductor lead-out area led out from the conductor connection area toward a lead-out direction projecting from the housing; and a reinforcing plate shaped in a planar shape with an insulating material, the reinforcing plate being sandwiched between the conductor connection area and the terminal lead-out area. The housing includes a protruded body protruded toward the conductor lead-out area side of the conductive component than a same plane with the terminal lead-out area.

An information handling system includes a first z-axis compression connector, a first dual in-line memory module (DIMM), a second z-axis compression connector, a second DIMM, and a printed circuit board. A first side of the first compression connector is affixed to the printed circuit board. A first surface of a first memory circuit board of the first DIMM is affixed to a second side of the compression connector. A first side of the second compression connector is affixed to a second side of the first memory circuit board. A first side of a second memory circuit board of the second DIMM is affixed to a second side of the second compression connector. The first compression connector has a first depth, and the second compression connector has a second depth that is different from the first depth.

A robot system that performs work of coupling a flexible cable to a connector provided on a board, includes a robot in which a gripping unit that grips the cable and a force detection unit that detects a force acting on the gripping unit are provided, a control unit that controls the robot to perform a conveyance action to grip the cable using the gripping unit and convey the cable onto the board, and an insertion action to insert the cable into the connector by force control based on a detection result in the force detection unit, an insertion speed entry part in which an insertion speed of the cable into the connector at the insertion action is entered, and a determination unit that can determine force control information necessary for the force control in the insertion action according to the insertion speed.

Various embodiments of the present disclosure are directed to electrically conductive connection between a first electrically conductive element and a second electrically conductive element on a textile carrier material. In one example embodiment, the electrically conductive connection includes an electrically conductive thermal transfer adhesive arranged on the carrier material and creates an electrically conductive connection between the first conductive element and the second conductive element. The electrically conductive connection is positioned in electrically conductive contact with the first conductive element and the second conductive element.