A circuit assembly includes a flexible card having a main panel and an extension panel foldably connected along a fold line and a card circuit disposed on the flexible card and having one or more contact points disposed proximate the fold line, and a circuit board having one or more electrical contacts formed on a surface of the circuit board. The flexible card and the circuit board can be disposed in face-to-face contact with each contact point of the card circuit is in registry with a respective electrical contact of the circuit board, with the extension panel folded at the fold line over the circuit board. The assembly includes a clip disposed over the folded extension panel and main panel to apply a sandwiching force to secure the circuit board and the card circuit in electrical contact.

An electrical assembly that includes a substrate having an aperture. A flat conductor is mounted to the substrate and extends over at least a portion of the aperture, with a ring terminal in contact with the flat conductor adjacent to the aperture. A lead wire connects to the ring terminal and is spaced from the substrate, and a fastener extends through the ring terminal and flat conductor, secured in the aperture, and securing the ring terminal against the flat conductor.

A flexible display device includes a flexible display panel and a chip on film (COF) bonded to the flexible display panel; wherein the flexible display panel is divided into a display region, a bonding region on a side of the display region, and a bending region between the display region and the bonding region; wherein the COF comprises a main body portion and two expansion bonding portions respectively disposed at two ends of one side of the main body portion; wherein an edge of the main body portion adjacent to the two expansion bonding portions are disposed with a plurality of connection pins; wherein the COF is bonded to the bonding region of the flexible display panel through the plurality of connection pins.

Glucose monitoring devices and related systems and methods, the glucose monitoring devices including a sensor electronics unit having a housing and a printed circuit board disposed within the housing, a transcutaneous glucose sensor assembly, and a conductive sensor connector. The printed circuit board includes a first electrical contact, the transcutaneous glucose sensor assembly includes a distal portion having a working electrode and proximal portion having a working-electrode contact in electrical communication with the working electrode, and the conductive sensor connector electrically connects the working-electrode contact with the first electrical contact. Further, the conductive sensor connector extends through a hole in the proximal portion of the transcutaneous glucose sensor assembly and through a hole in the printed circuit board.

A wearable physiologic state monitoring device includes a textile fabric, a flexible sensing unit, and a control unit. The textile fabric has a first surface and a second surface opposite to each other. The flexible sensing unit is joined to the first surface of the textile fabric and has a flexible substrate and a sensing element. The flexible substrate has a bearing surface, and a patterned conductive circuit is provided on the bearing surface. The sensing element is electrically connected to the patterned conductive circuit. The control unit is adjacent to the flexible sensing unit and is electrically connected to the patterned conductive circuit.

An apparatus and method, the apparatus comprising: a layer of quantum tunnelling composite configured such that in a non-compressed state the quantum tunnelling composite is an electrical insulator and in a compressed state the layer of quantum tunnelling composite is an electrical conductor; a magnetic portion configured to cause compression of the quantum tunnelling composite; and wherein the apparatus is configured to be coupled to a reciprocal apparatus where the reciprocal apparatus comprises a reciprocal magnetic portion such that when the apparatus is coupled to the reciprocal apparatus the magnetic portion causes compression of the quantum tunnelling composite to provide a direct current path through the quantum tunnelling composite to the reciprocal apparatus.

The present invention relates to a substrate unit and a substrate assembly, and a camera module using the same. The present invention may comprise: a first substrate part having rigidity; a second substrate part stacked on one surface of the first substrate part and having flexibility; a third substrate part extending outwardly from the second substrate part and having flexibility; and a reinforcing part which is disposed at a portion where the edge portions of the first substrate part and the third substrate part meet, the reinforcing part having a recessed portion which is formed by recessing the first substrate part inwardly so as to inhibit interference between the first substrate part and the third substrate part. The present invention is capable of resolving the interference between a rigid PCB and a flexible PCB and the tearing thereof by providing a reinforcing part in a connection portion of the rigid PCB and the flexible PCB.

An implantable electrical connecting device includes a first elastic multi-ply layer and a second elastic multi-ply layer. The first elastic multi-ply layer has a first electrically conductive layer and a plurality of first electrical contacts electrically conductively connected to the first electrically conductive layer of the first elastic multi-ply layer. The second elastic multi-ply layer has a first electrically conductive layer and a plurality of second electrical contacts electrically conductively connected to the first electrically conductive layer of the second elastic multi-ply layer. The second electrical contacts make contact with the first electrical contacts.

A carrier assembly may include a first carrier sub-assembly, said first carrier sub-assembly having an elongated shape and comprising at least one electrically conductive layer structure and at least one electrically insulating layer structure, said at least one electrically conductive layer structure extending up to a first area provided on one of two extremities of the elongated shape, wherein a first plurality of conductive nanowires is provided on said first area, and a second carrier sub-assembly, said second carrier sub-assembly comprising at least one electrically conductive layer structure and at least one electrically insulating layer structure, said at least one electrically conductive layer structure comprising a second area, wherein a second plurality of conductive nanowires is provided on that second area.

An apparatus and method to reliably attach an electronic module to a textile. The overall mechanical assembly of the invention includes: (a) light pipe, (b) top enclosure, (b) magnet, (c) main electronics which contains (d) the main PCB, (e) battery and (f) other electronic components, (g) bottom enclosure, which holds (h) the connector PCB, (i) module dock, (j) top textile PCB which are located above the (j) textile band and under the (k) textile pocket and the (l) bottom textile PCB and (m) fabric and laminate padding, which are located below the textile band. The invention is physically embodied by an electronic module, comprising at least one printed circuit board (PCB), comprising at least one conductive circuit and at least one electronic component; a metallic rivet, grommet or eyelet to mechanically and electrically connect the; and a textile substrate with at least one electrically conductive circuit.