A control device for mounting in electrical heated wearables for controlling power to electrical heating wires secured in the heated wearables and capable of charging one or more portable batteries associate therewith and communicating data relative thereto. The control device has a finger-operable switch integrated with electronic circuits mounted on a pcb board. The electronic circuits include a communication circuit to interface with a wearer person to provide message information to the wearer person. The electronic circuits has power input terminals adapted to receive operating voltage from the one or more portable batteries. The pcb board with the finger-operable switch, the wiring connections and the electronic circuits are encapsulated by waterproof material. A female USB symmetrical input connecting port is mounted at a user accessible location on the control device and isolated from the pcb board and the electronic circuits by a further waterproof material. The female USB symmetrical input connecting port has a cable connection capable of transmitting power and data to the electronic circuits and power input terminals. The female USB symmetrical input connecting port is oriented to provide access to a symmetrical male plug connector secured to a power supply cable capable for supplying voltage from an auxiliary battery supply or charger and for the transmission of data information.

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.

Methods and apparatus relating to wireless warmers are described. An embodiment integrates wireless warming into an article of clothing. For example, the article of clothing includes a heating element to receive electromagnetic energy from one or more wireless power transmitter coils based at least in part on one or more signals. Other embodiments are also disclosed and claimed.

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.

A garment with electrical components is described. The garment comprises a garment body, a power management unit, at least one battery operatively connected to the power management unit, at least one electrical element operatively connected to the power management unit, the electrical element being connected to the at least one battery via the power management unit, and an electrical connection operatively connected to the power management unit for connecting the power management unit to a power supply external to the garment, the power management unit being operable to select between a distribution of power from at least the at least one electrical connection to at least one of the at least one electrical element and the at least one battery, and the at least one battery to the electrical element. A vehicle and garment system and a method for distributing power in a garment are also disclosed.

An interactive device includes a housing, configured to be positioned on or adjacent a heat-receiving surface. The housing includes a plurality of controlled-response elements for outputting heat in response to the controlled-response elements receiving a first energy input.

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 lawn mower has an electrical port that receives current from an alternator powered by the lawn mower engine. The current and voltage sent the electrical port depend on a flywheel and stator arrangement operatively connected to the alternator. The stator may be replaceable or interchangeable to selectively determine the alternator current and voltage output. The port receives a plug from a garment worn by the lawn mower operator. The garment includes one or more thermo-electric elements that are powered from current extending through the port. The thermo-electric elements may be resistive heaters to warm the operator or TEC coolers to cool the operator. Furthermore, the garment may include a rechargeable battery that powers the thermo-electric elements when the plug is disconnected from the port.

A lawn mower has an electrical port that receives current from an alternator powered by the lawn mower engine. The current and voltage sent the electrical port depend on a flywheel and stator arrangement operatively connected to the alternator. The stator may be replaceable or interchangeable to selectively determine the alternator current and voltage output. The port receives a plug from a garment worn by the lawn mower operator. The garment includes one or more thermo-electric elements that are powered from current extending through the port. The thermo-electric elements may be resistive heaters to warm the operator or TEC coolers to cool the operator. Furthermore, the garment may include a rechargeable battery that powers the thermo-electric elements when the plug is disconnected from the port.

An outdoor power unit or lawn mower has an electrical port that receives current from an alternator powered by the lawn mower engine. The current and voltage sent the electrical port depend on a flywheel and stator arrangement operatively connected to the alternator. The stator may be replaceable or interchangeable to selectively determine the alternator current and voltage output. The port receives a plug from a garment worn by the lawn mower operator. Alternatively, the outdoor power unit may be an entirely electric device free of an internal combustion engine. The garment includes one or more thermo-electric elements that are powered from current extending through the port. The thermo-electric elements may be resistive heaters to warm the operator or TEC coolers to cool the operator. Furthermore, the garment may include a rechargeable battery that powers the thermo-electric elements when the plug is disconnected from the port.