A flexible electric heating device includes a planar flexible carrier foil, at least two electrically conductive bus lines attached to a surface of the carrier foil, and at least one electric heating member, including first and second electrically conductive electrodes, electrically connected to one of the bus lines. Each electrode has at least one curved edge, wherein the curved edges are located at a distance and are facing each other. The heating member further includes a resistive heater layer, at least partially overlapping the curved edges of the electrodes to form a resistive connecting region. The curved edges are arranged such that locations of the resistive connecting region are facing the first electrode or the second electrode in directions parallel to at least three mutually orthogonal directions that lie in the carrier foil, wherein one of the orthogonal directions is aligned parallel to an edge of the carrier foil.

A self regulating heating device includes a first layer made of an electrically insulating material. The first layer is thin and flexible. First and second buses spaced from each other are connected to the first layer. A resistive layer electrically connects the first and second buses. The resistive layer has a higher electrical resistance than the second layer. The resistive layer experiences a positive temperature coefficient (PTC) effect when heated. A solar active layer is connected to the first layer. The solar active layer is electrically connected to the first and second buses. The solar active layer converts light into electrical energy to apply a voltage across the first and second buses.

At least some aspects of the present disclosure direct to a device including a conductive heater and a convective device. The conductive heater includes a first conductive bus and a second conductive bus, a first set of electrodes electrically connected to the first conductive bus, a second set of electrodes electrically connected to the second conductive bus, wherein the first and the second set of electrodes are interdigitated, and a plurality of heater stripes comprising printed ink and electrically connected to the first and the second sets of electrodes. The convective device includes a pneumatic structure and an opening into the pneumatic structure connected to an inflation medium source, wherein at least part of the convective device is air permeable. The application is further directed to a warming device comprising a gown and said device, wherein the conductive heater and convective device are disposed on or integrated with the gown.

A heater system for an LED light assembly having a lens includes a flexible composite positioned around an outer surface of the lens. The flexible composite includes a polymer base layer, a plurality of conductive buses provided on the base layer, and a resistive layer electrically connecting the plurality of buses to form a circuit. The resistive layer includes conductor particles dispersed in a polymer matrix. The resistive layer has a crystalline first condition prior to applying electricity to one of the buses and an amorphous second condition in response to applying electricity to one of the buses.

The invention relates to a heated sensitive layer sensor comprising an insulating substrate bearing the sensitive layer; two complementary measurement electrodes in the form of two adjacent conductive tracks configured in electrical contact with the sensitive layer; and a heating element in the form of a resistive track arranged on the substrate for uniformly heating an active area of the sensitive layer. The resistive track comprises at least three power supply points regularly spaced over the length of the resistive track, and each point of even rank is supplied at a first supply voltage and each point of odd rank is supplied at a second supply voltage.

A low-power transparent electro-thermal film device is provided. The device includes a transparent substrate, a transparent conductor layer disposed at least one side of the transparent substrate, and a plurality of inner electrodes disposed on the transparent conductor layer and including a first plurality of inner electrodes extending in a comb shape from a first electrode bus bar and a second plurality of inner electrodes extending in the comb shape from a second electrode bus bar. The first plurality of inner electrodes inter-lock with the second plurality of inner electrodes.

A seat cushion includes a support member. A cover encloses the support member. A self-regulating heating device extends between the support member and an upper portion of the cover.

A low-power transparent electro-thermal film device is provided. The device includes a transparent substrate, a transparent conductor layer disposed at least one side of the transparent substrate, and a plurality of inner electrodes disposed on the transparent conductor layer and including a first plurality of inner electrodes extending in a comb shape from a first electrode bus bar and a second plurality of inner electrodes extending in the comb shape from a second electrode bus bar. The first plurality of inner electrodes inter-lock with the second plurality of inner electrodes.

A heater panel includes a core. A heater/dielectric layer including a positive thermal coefficient (PTC) heater layer between a pair of dielectric layers is bonded to the core in a stack. An impact layer is bonded to the stack, wherein the impact layer includes a first sub-layer for impact absorption that is bonded to the stack and a second sub-layer for cut resistance bonded to the first sub-layer. The second sub-layer has a higher material hardness than that of the first-sub layer.

A heat generating body includes a heater unit that is integrally formed with plural placement portions and that generates heat when current is passed through the heater unit, and plural electrodes that are provided at the heater unit and that are each disposed at a different one of the plurality of placement portions to each other.