The invention concerns an article of clothing (10) comprising at least two conductive wires capable of transmitting an electric current, at least one conductive wire being integrated into at least one flat seam (12a); and at least one electrical interconnection between the at least two conductive wires; the electrical interconnection incorporating a weld (25) between the at least two conductive wires; the electrical interconnection is protected by two layers of fabric (21-23) attached respectively above and below the electrical interconnection; a lower layer of fabric (22) bonded to the article of clothing (10) above which the at least two conductive wires extend; and an upper layer of fabric (23) bonded to the lower layer of fabric (22) so as to form, with the lower layer of fabric (22), a protective barrier around the electrical interconnection.

The present invention relates to heatable garments (1), comprising a garment body (3) and a heating pad (5) adhered to at least a portion of the garment body (3), wherein the heating pad (5) comprises graphene particles dispersed in a polymer matrix material. The invention also provides fabrics for making such garments, and methods of making such garments and fabrics. Also provided are heatable bedding incorporating a heating pad as described above.

In one example, a heating and cooling garment system includes a garment, and a plurality of heating and cooling zones positioned within a portion of the garment. Each heating and cooling zone is configured to independently heat or cool based on heating and/or cooling instructions received from a mobile application executed on a wireless device.

The present disclosure generally relates to a textile (100) and a manufacturing method (200) thereof. The textile (100) comprises: a fabric body (102) formed from one or more types of yarns; a continuous channel (104) formed within the fabric body (102); and an insulated conductive element (106) disposed within the continuous channel (104), wherein the textile (100) is heatable in response to electrical current being conducted through the insulated conductive element (106).

An all-inclusive electrical heating liner for use in the fabrication of articles of different sizes requiring to be heated is disclosed. It is comprised of a thermally insulating fabric piece which is shaped to define two or more panels to which are secured patterns of heating wires at specific locations. The spaced relationship between the two or more panels is adjustable whereby the liner can be incorporated in articles of different sizes. The adjustments are made by adjustable band sections provided with delineated line formations permitting specific pleating and securement and wherein a wire interconnecting the patterns of heating wires detachably extends across the delineated line formations. The liner incorporates a power supply, controls, switches, wiring, connectors and other components thereby facilitating the incorporation of the liner into an article of different sizes resulting in a cost reduction to the manufacturer of such heated articles. Various embodiments are described to show that the all-inclusive one-piece heating liner is adaptable to many articles, such as pants sleeping bags and bags which require control heating.

A temperature controllable textile illustrated by the present disclosure has a first conductive cloth and a second conductive cloth. The first conductive cloth has a first metal while the second conductive cloth has a second metal different from the first metal. The first conductive cloth and the second conductive cloth have a thickness. A side surface of the first conductive cloth is in contact with a side surface of the second conductive cloth, and the first conductive cloth electrically connects to the second conductive cloth, to form two junction portions. When a negative end and a positive end of a direct current power electrically connects respectively with a top surface and a bottom surface of the first conductive cloth, the two junction portions form a cooling end and a heating end, respectively.

A smart fabric may include a smart material such as an Electroactive Polymer (EAP). An adaptive garment formed from the smart fabric may change textile density based on user needs, sensor states, context, and other inputs. In various embodiments, the EAP enables the adaptive garment to change textile density based on a sport or activity, based on calendar or scheduled events, or based on user preferences. In various embodiments, these smart fabrics may be implemented in sporting garments, uniforms, multiple-day clothing (e.g., for travel or military usage), furniture fabric, curtains, or other implementations.

A temperature controllable textile having first, second and third conductive cloths and first and second conductive type semiconductor films is illustrated. When positive and negative ends of a direct current power electrically connect to the first and second conductive cloths respectively, first and third junction ends which first and second conductive cloths respectively contact and electrically connect to the first and second conductive type semiconductor films function as a cooling end, and second and fourth junction ends which the third conductive cloth contacts and electrically connect to the first and second conductive type semiconductor films function as a heating end, or the first and third junction ends function as the heating end, and the second and fourth junction ends function as the cooling end.

An electronic heating/cooling garment includes: a neck part, a collar (neckband), or an underarm part where a Peltier device (31) is placed; and a front body or a back body where a heating medium circulation path (35) and a battery (35) are placed, the battery (35) being configured to supply electric power to a pump (341) and the Peltier device (31). The heating medium circulation path (35) is composed of a flexible thermally conductive material having a tubular shape and holds a heating medium therein in an airtight manner. The heating medium circulation path has a first electrode and a second electrode on its outer surface. The first and second electrodes are configured to supply the electric power from the battery (35) to the Peltier device (31) and the pump (341).

An all-inclusive electrical heating liner for use in the fabrication of articles of apparel is disclosed. It is comprised of a thermally insulating fabric piece which is shaped to define a dorsal panel and a pair of frontal panels to which are secured patterns of heating wires at specific locations. The spaced relationship between the dorsal panel and the pair of frontal panels is adjustable whereby the liner can be incorporated in articles of apparel of different sizes including small. Medium, large and X-large apparel sizes and gender types. The liner incorporates a power supply, controls, switches, wiring, connectors and other components thereby facilitating the incorporation of the liner into an article of apparel resulting in a cost reduction to the manufacturer of heated articles of apparel. Various embodiments are described to show that the all-inclusive one-piece heating liner is adaptable to many articles which require control heating.