The present invention provides a portable system for cooling that is integrated into a wearable garment or carrying device. The device includes a Peltier thermoelectric cooler coupled to the garment. The thermoelectric cooler comprises a cold side plate and a hot side plate. The cold side plate is oriented proximate to the body of the wearer. The cooling device further comprises a thermal shield. The thermal shield comprises a thermally reflective surface that faces the wearer side of the garment. The device comprises a thermal conduction sheet coupled to the cold side of the thermoelectric cooler. The device further comprises a cold pack thermally coupled to a side of the thermal conduction sheet. The device comprises a blower configured to blow air across the hot side of the thermoelectric cooler and away from the garment.

A graphene silicone sticky sheet and compound structure using the same is provided. The graphene silicone with PU function group is used as substrate which is further combined with an adhering layer so as to form as a graphene silicone sticky sheet. Therefore, it is adhered to various application objects, especially clothes or wearing objects, such as an eye mask. Further, the graphene silicone can be combined with conductive wires which extend outwards and thus it can be made as electrode adhesive sheet or electric heating sheet.

A heated garment including a garment body, a heater coupled to the garment body, and a controller for controlling the heater including an electronic processor. The controller is configured to receive an input signal indicating a first heater mode, determine a requested heater temperature level based on the first heater mode, determine a temperature, determine, based on the temperature, that the heater is able to maintain the requested heater temperature level for a first period of time, set a heater temperature level to the requested heater temperature level for the first period of time, and set the heater temperature level to a second temperature for a second period of time after the first period of time has elapsed.

A heating element composite comprises a substrate of one or more fibers or threads and an electrically-conductive polymer coating comprising an electrically-conductive polymer material deposited onto the one or more fibers or threads. A thickness of the electrically-conductive polymer coating is at least about 100 nanometers and the electrically-conductive polymer coating covers at least about 75% of an external surface area of the one or more fibers or threads of the substrate. The resulting heating element composite has a sheet resistance of from about 2Ω/□ to about 200Ω/□.

This present disclosure relates to a flexible heating device having a unique layered assembly structure including a flexible heat generating layer. The present disclosure also relates to a method of manufacturing the flexible heating device and method of use of the flexible heating device in various applications.

Embodiments include a heating blanket. The heating blanket may include a heating element and a shell covering the heating element. The heating element has elastic properties and is disposed in the shape of a sheet. The shell may have one or more sheets of polymeric material bonded together adjacent a perimeter of the heating element. One or more wires having malleable properties are secured within the shell. The wires allow the heating blanket to be secured to a patient.

A temperature regulated apparatus can include a layered member comprising a first layer of material and a second layer of material connected to the first layer. The layered member can have a first opening formed therein and an interior area defined by the first layer and the second layer. The interior area can be in communication with the first opening. A temperature regulating element adapted to alter the temperature of the layered member can be positioned within the interior area of the layered member, and can be removed from the layered member without disassembling the layered member.

The disclosure provides an apparatus, system and method for a flexible heater suitable for embedding in a wearable. The flexible heater comprises a conformable substrate; a matched function ink set, printed onto at least one substantially planar face of the substrate to form at least a conductive layer capable of receiving current flow from at least one power source; a resistive layer electrically associated with the at least one conductive layer and comprising a plurality of heating elements capable of generating heat upon receipt of the current flow; and a dielectric layer capable of at least partially insulating the at least one resistive layer, wherein the matched ink set is matched to preclude detrimental interactions between the printed inks of each of the at least one conductive, resistive and dielectric layers, and to preclude detrimental interactions with the conformable substrate.

An electrically heatable, above-the-calf, oversock is formed by interconnected fabric sections. The oversock defines a foot section and a leg section interconnected with one another. The foot section has a toe heating section secured thereto. The leg section is formed of interconnected pattern fabric panels secured together by thread seams. In one embodiment of the oversock, the pattern fabric panels include two elongated side fabric panels extending from a top end of the leg section to the foot section, a front panel and a rear panel. At least the lateral one of the two elongated side fabric panels is formed by two or more superimposed side panel pattern pieces interconnected to one another by stitch seams and defining there between a channel through which extends a power feed wire from a switch secured in a upper part of the channel and accessible from an outer surface of the lateral side panel. The feed wire extends to the toe heating section where it is secured to a toe heating wire. An oversock retainer is secured about a top end of the leg section for retention of the oversock above the calf of a wearer person's leg.

The disclosure provides an apparatus, system and method for a flexible heater suitable for embedding in a wearable. The flexible heater comprises a conformable substrate; a matched function ink set, printed onto at least one substantially planar face of the substrate to form at least a conductive layer capable of receiving current flow from at least one power source; a resistive layer electrically associated with the at least one conductive layer and comprising a plurality of heating elements capable of generating heat upon receipt of the current flow; and a dielectric layer capable of at least partially insulating the at least one resistive layer, wherein the matched ink set is matched to preclude detrimental interactions between the printed inks of each of the at least one conductive, resistive and dielectric layers, and to preclude detrimental interactions with the conformable substrate.