Provided is a flexible printed wiring board including: a base film which is an insulating layer; a first conductor layer; a second conductor layer; and a through-hole, in which the first conductor layer is provided on one surface of the base film, the second conductor layer is provided on the other surface of the base film, and the through-hole is provided so as to penetrate the base film and electrically connect the first conductor layer and the second conductor layer to each other, and the second conductor layer has a solderable region.

Provided is a flexible printed wiring board including: a base film which is an insulating layer; a first conductor layer; a second conductor layer; and a through-hole, in which the first conductor layer is provided on one surface of the base film, the second conductor layer is provided on the other surface of the base film, and the through-hole is provided so as to penetrate the base film and electrically connect the first conductor layer and the second conductor layer to each other, and the second conductor layer has a solderable region.

A trunk cable 12 includes a signal trunk conductor 31 that is electromagnetically shielded by a shield layer 35. A branch cable 13 includes a signal branch conductor 38 that is electromagnetically shielded by a shield layer 42. The signal trunk conductor 31 and the signal branch conductor 38 are electrically connected to each other by a relay bus bar 64 that is electromagnetically shielded by a base shielding member 65 and a cover shielding member 27.

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.

Provided are terminal-free connectors for flexible interconnect circuits. A connector comprises a housing chamber defined by at least a first side wall and a second side wall oppositely positioned about the base. An edge support is positioned at each of the first side wall and the second side wall. The edge supports allow for precise placement of the flexible interconnect circuit inside the housing chamber. A cover piece is coupled to the base via a first hinge, and is configured to move between a released position and a clamped position. The cover piece includes a clamp portion securing the flexible interconnect circuit against the edge supports in the clamped position. A slider may be configured to move between an extended position and an inserted position within the housing chamber, and may include a convex upper surface configured to urge the flexible interconnect circuit upwards in the inserted position.

According to one embodiment, a semiconductor storage device includes: a casing, a first board, a second board, a semiconductor memory component, a connector, and a flexible conductive part. The first board is in the casing. The second board is in the casing. The semiconductor memory component is in the casing. The semiconductor memory component is on the first board. The connector is connectable to a host device. The connector is mounted on the second board, the connector protruding from the casing. The flexible conductive part is between the first board and the second board. The flexible conductive part electrically connects the first board and the second board. The flexible conductive part is bendable.

A display apparatus includes a display panel, a touch layer, and a flexible printed circuit (FPC) including a main FPC and a bridge FPC. A third soldering region and a fourth soldering region of the bridge FPC are respectively soldered to a first soldering region and a second soldering region of the main FPC. Ends of each first touch connection line are electrically connected to a touch chip and a first touch lead. Ends of each second touch connection line are electrically connected to a pad on the second soldering region and a second touch lead. Ends of each third touch connection line are electrically connected to a pad on the first soldering region and the touch chip. Ends of each touch transfer line are electrically connected to a pad on the third soldering region and a pad on the fourth soldering region.

A connection device electrically connects a textile to an electrical contact of a connector. The connection device is received in an insertion direction in the connector. The connection device includes a body and an attachment device. The body has a first end and a second end opposite the first end in the insertion direction. The body has a first surface extending between the first end and the second end and a second surface opposite to the first surface. The body has a portion at the first end extending essentially transversely from the first surface, the portion having an aperture into which the textile is inserted. The attachment device for the textile is connected to the second surface at the first end.

Backplane employing floating backplane network interconnects for electrical coupling with blade computer systems and related methods. To provide a displacement tolerant interconnection system between the backplane interconnects and respective blade backplane interconnects of blade computer systems to establish electrical connections therebetween, the backplane interconnects are provided as floating backplane interconnections. The floating backplane interconnects are configured to move and be displaced relative to the backplane while still retaining an electrical connection to the backplane. The backplane interconnects each include one or more flex circuits connected to electrical interconnects on the backplane on a first end, and electrical interconnects on a backplane connector on a second end. The flex circuit(s) include an electrical cable that includes a polymer or other material surrounding electrical wires to allow the flex circuit and its internal electrical wires to bend and flex, and thus move relative to backplane.

Connector inserts and connector receptacles that have a small form factor and where when a connector insert and connector receptacle are mated, the connector insert can rotate and articulate relative to an electronic device housing the connector receptacle. The connector receptacle can be connected to components in the electronic device through a flexible circuit board having an amount of slack or excess length to allow the connector receptacle and the connector insert to rotate relative to the connected components. A bearing supporting the connector receptacle can articulate about an axis to allow the connector receptacle and connector insert to articulate relative to the connected components. The bearing can further support a locking mechanism to lock the connector insert in place in the connector receptacle.