The present invention relates to a textile device (1) configured to cooperate with an electronic device (2) comprising conductive path (21) having a path connection area (22). The textile device (1) comprises a first portion of textile (10) including a conductive zone (11) connected to a stretchable connection area (12) configured to be in contact with the path connection area (22) of the conductive path (21) so as to ensure an electrical connection between said textile device (1) and said electronic device (2). The stretchable connection area (12) comprises a conductive textile or a textile covered with a flexible conductive film. The textile device (1) also comprises a compartment, defined between the first portion of textile (10) and a second portion of textile (13), configured to maintain the electronic device (2) in a predefined position ensuring electrical connection between the stretchable connection area (12) and the path connection area (22).

Apparatus, comprising fabric (62) formed from fibers (74); and an electrical component (20) having first and second perpendicular fiber guiding structures, wherein a first of the fibers is soldered in the first fiber guiding structure and a second of the fibers is soldered in the second fiber guiding structure.

A system compatible for use with ATCA includes a chassis comprising a first and a second plurality of slots for receiving circuit boards. The chassis further includes a midplane having a front surface and a back surface. The midplane extends between the first plurality of slots and the second plurality of slots. The midplane has a first plurality of connectors affixed to the front surface and has a second plurality of connectors affixed to the back surface. Each connector is arranged to accept a circuit board. The midplane forms an interconnection scheme such that one of the first plurality of slots is directly connected to one of the second plurality of slots. The one of the first plurality of slots and the one of the second plurality of slots extend in opposite directions from their respective connections on the midplane.

Described herein are apparatuses (e.g., garments, including but not limited to shirts, pants, and the like) for detecting and monitoring physiological parameters, such as respiration, cardiac parameters, and the like. Also described herein are methods of forming garments having one or more stretchable conductive ink patterns and methods of making garments having one or more highly stretchable conductive ink pattern formed of a composite of an insulative adhesive, a conductive ink, and an intermediate gradient zone between the adhesive and conductive ink. The conductive ink typically includes between about 40-60% conductive particles, between about 30-50% binder; between about 3-7% solvent; and between about 3-7% thickener. The stretchable conductive ink patterns may be stretched more than twice their length without breaking or rupturing.

A conductive tape formed by laying a conductive pathway on a tape layer is disclosed. Various apparatus and methods for laying conductive pathways to form conductive tape are disclosed. The conductive pathways may be laid by varying the lateral position of the conductive pathway on the tape substrate. Such patterns all stretchable conductive tape to be realized. Multiple conductive pathways may be laid in the tape and the lateral separation of the pathways in the tape may vary. In some embodiments the pathways are formed from conductive yarn or by printing or laying conductive ink.

Described herein are molecular inks, methods for printing the molecular inks on flexible substrates, and methods for forming printed electronic elements, such as resistive heaters, force sensors, motion sensors, and devices that include these elements, such as force responsive conductive heaters. The methods include printing a molecular ink on a flexible substrate that is heated to 30° C. to 90° C. before and/or during the printing process and curing the substrate to produce a conductive pattern thereon. The molecular inks generally include a particle-fee metal-complex composition formulated from at least one metal complex and a solvent, and optionally, a conductive filler material, and/or surfactant.

A system comprises an article comprising one or more fabric layers, a plurality of electronic devices, each being incorporated into or onto one of the one or more fabric layers, and one or more communication links between two or more of the plurality of electronic devices. Each of the plurality of electronic devices can comprise a flexible substrate coupled to the fabric layer, one or more metallization layers deposited on the flexible substrate, and one or more electronic components electrically coupled to the one or more metallization layers.

There are provided a printed circuit board and a method of manufacturing the same. The printed circuit board include a glass plate, an insulating member penetrating through the glass plate, insulating layers disposed on a first surface and a second surface of the glass plate, and a via through the insulating member.

The present disclosure relates to a smart textile product and a method for manufacturing a smart textile product. The smart textile product is provided with a flexible and/or stretchable textile fabric (10) comprising a plurality of electrically conductive threads (11, 12) and at least one rigid electronic or optoelectronic component (20) comprising at least one electrically conductive pad (21, 22), which is in electrical contact with at least one of the plurality of electrically conductive threads. The smart textile product (10) comprises an elastomeric encapsulation layer (31) in which the electrical connection (1, 2) is embedded, so as to provide a gradual transition in deformability between the flexible and/or stretchable textile fabric (10) and the at least one rigid component (20) at the location of the at least one electrical connection (1, 2).

A roll-to-roll printing process for large scale manufacturing of nanosensor systems for sensing pathophysiological signals is disclosed. The roll-to-roll manufacturing process may include three processes to improve the throughput and to reduce the cost in manufacturing: fabrication of textile based nanosensors, printing conductive tracks, and integration of electronics. The wireless nanosensor systems can be used in different monitoring applications. The fabric sheet printed and integrated with the customized components can be used in a variety of different applications. The electronics in the nanosensor systems connect to remote severs through adhoc networks or cloud networks with standard communication protocols or non-standard customized protocols for remote health monitoring.