An ECG sensor system comprising: a substrate having a first side and a second side, the substrate of a non-conducting material; a plurality of textile-based sensors positioned on the first side, each of the plurality of textile-based sensors spaced apart from one another on the first side, the second side covering one side of the each of the plurality of textile-based sensors as an insulating covering, the each of the plurality of textile-based sensors including conductive fibres interlaced with one another; and a conductive trace connected to the each of the plurality of textile-based sensors, each of the conductive traces for connecting the plurality of textile-based sensors to an electronic controller for sending and receiving electronic signals from a selected pair of the plurality of textile-based sensors.

An ECG sensor system comprising: a substrate having a first side and a second side, the substrate of a non-conducting material; a plurality of textile-based sensors positioned on the first side, each of the plurality of textile-based sensors spaced apart from one another on the first side, the second side covering one side of the each of the plurality of textile-based sensors as an insulating covering, the each of the plurality of textile-based sensors including conductive fibres interlaced with one another; and a conductive trace connected to the each of the plurality of textile-based sensors, each of the conductive traces for connecting the plurality of textile-based sensors to an electronic controller for sending and receiving electronic signals from a selected pair of the plurality of textile-based sensors.

Provided are a cloth and a protective product, which allow for any color appearance and have excellent protection performance against electric arcs. The cloth has a woven fabric structure, wherein a front-surface spun yarn containing an infrared absorber- and/or electrically conductive agent-containing fiber and not containing carbon is located on a front surface, while a back-surface spun yarn containing a carbon-containing fiber is located on a back surface, and the cloth has an ATPV value of 8.0 cal/cm.sup.2 or more in Arc Resistance Test ASTM F1959-1999.

Provided are a cloth and a protective product, which allow for any color appearance and have excellent protection performance against electric arcs. The cloth has a woven fabric structure, wherein a front-surface spun yarn containing an infrared absorber- and/or electrically conductive agent-containing fiber and not containing carbon is located on a front surface, while a back-surface spun yarn containing a carbon-containing fiber is located on a back surface, and the cloth has an ATPV value of 8.0 cal/cm.sup.2 or more in Arc Resistance Test ASTM F1959-1999.

A wearable sensor, a forming method therefor, and a sensor module. The wearable sensor includes elastic yarns made of an elastic material; and conductive yarns. The conductive yarns and the elastic yarns interweave and form a fabric structure. The conductive yarn has a first end, a second end, and a body portion between the first end and the second end, the body portion include an entry section extending from the first end toward a fold-back region and an exit section returned back from the fold-back region, the entry section and the exit section form at least one intersection, and the entry section and the exit section come into contact at the intersection. In addition to providing the sensing measurement function, said sensor can improve the user experience, and can expand the application field of the sensor.

A system of fibre based temperature sensor integrated into abase fabric layer for a garment, the system comprising: a set of wall fibres interlaced with one another to form a first wall structure defining a first cavity along a length and a second wall structure defining a second cavity along the length, the set of wall fibres comprising nonconductive material; at least one conductive fibre miming along the length within each cavity, such that the set of wall fibres of the wall structures encloses each at least one conductive fibre in order to electrically insulate each at least one conductive fibre from an environment along the length external to the cavities; and a set of base fibres interlaced with one another to form the base fabric layer.

A system of fibre based temperature sensor integrated into abase fabric layer for a garment, the system comprising: a set of wall fibres interlaced with one another to form a first wall structure defining a first cavity along a length and a second wall structure defining a second cavity along the length, the set of wall fibres comprising nonconductive material; at least one conductive fibre miming along the length within each cavity, such that the set of wall fibres of the wall structures encloses each at least one conductive fibre in order to electrically insulate each at least one conductive fibre from an environment along the length external to the cavities; and a set of base fibres interlaced with one another to form the base fabric layer.

A wrappable woven sleeve includes a wall having opposite edges extending lengthwise between opposite ends. The opposite edges are configured to be wrapped about a central longitudinal axis, whereupon the wall takes on a tubular configuration with an inner surface of the wall bounding an enclosed cavity sized for receipt of an elongate member to be protected therein and an outer surface of the wall facing radially outwardly from the central longitudinal axis. The wall is woven with warp filaments extending generally parallel to the central longitudinal axis and weft filaments extending generally transversely to the warp filaments. One or more of the warp filaments are wire to shield against passage of low frequency EMI. A foil layer is fixed to the outer and/or inner surfaces of the wall to shield against passage of high frequency EMI.

A wrappable woven sleeve includes a wall having opposite edges extending lengthwise between opposite ends. The opposite edges are configured to be wrapped about a central longitudinal axis, whereupon the wall takes on a tubular configuration with an inner surface of the wall bounding an enclosed cavity sized for receipt of an elongate member to be protected therein and an outer surface of the wall facing radially outwardly from the central longitudinal axis. The wall is woven with warp filaments extending generally parallel to the central longitudinal axis and weft filaments extending generally transversely to the warp filaments. One or more of the warp filaments are wire to shield against passage of low frequency EMI. A foil layer is fixed to the outer and/or inner surfaces of the wall to shield against passage of high frequency EMI.

In a textile for a non-woven fabric, the obverse surface side on which the non-woven fabric is conveyed is coated with a rubber resin classified into the R group of JISK6397 (rubber having an unsaturated carbon bond on the main chain).