A heating pad includes a heat pad with an anterior and posterior side. The heat pad includes a first layer, a second layer, and a third layer. The second layer is located in between the first layer and the third layer. The first layer is located on the posterior side, while the third layer is located on the anterior side. The second layer has a wire selectively heated to increase the temperature of the heat pad. The third layer is a reflective material positioned to reflect heat from the second layer towards the first layer, decreasing heat emitted on the anterior side of the heat pad. The heating pad also includes a battery storage section for securing a battery. The battery is in electronical communication with the wire of the heat pad. The heating pad further includes an engagement mechanism to secure the heating pad to a user.

An aerosol-generating system is provided, including a fluid-permeable electric heater assembly, the heater assembly including an electrically insulating substrate, an aperture being formed in the electrically insulating substrate, and a heater element having a first face fixed to the electrically insulating substrate, the heater element spanning the aperture and including a plurality of electrically conductive filaments connected to first and second electrically conductive contact portions, the first and second electrically conductive contact portions positioned on opposite sides of the aperture to one another, wherein the first and second electrically conductive contact portions are configured to allow contact with an external power supply.

An electrical connection assembly includes a cable having a conductor, a metallic textile in electrical contact with the conductor, and a crimp element creating a pressure between the conductor and the metallic textile.

A thermoelectric device including a panel, formed of a thermally insulating material, and having a plurality of thermoelectric elements including compacted conductors inside the insulating material and expanded conductors outside the insulating material wherein the thermoelectric elements run substantially parallel to or at an acute angle relative to the long dimension of the panel. The thermoelectric device may be integrated into a variety of surfaces or enclosures needing heating or cooling with controls and configurations to optimize the application.

A cartridge for an aerosol-generating system is provided, including: a liquid storage portion including a housing containing a liquid aerosol-forming substrate, the housing having an open end; and a fluid-permeable heater assembly including: an electrical heating element configured to heat the liquid aerosol-forming substrate to form an aerosol, the electrical heating element including a planar filament arrangement having one or more electrically conductive filaments, an electrically insulating substrate including a ceramic material and having a planar attachment face, the filament arrangement disposed in contact with the planar attachment face, and connectors arranged at opposite ends of the electrical heating element and forming two separate electrical contacts configured to apply power to the filament arrangement, the fluid-permeable heater assembly being arranged over the open end of the housing.

An aerosol-generating system is provided, including: an aerosol-generating device including a power source; and a cartridge removably coupled to the device, the cartridge including a liquid storage portion including a housing having an open end and containing a liquid aerosol-forming substrate, a substantially flat heater assembly fixed to the open end of the housing and including an electrical heating element arranged in a curved manner and configured to heat the substrate to form an aerosol, and a capillary material disposed in contact with the heating element and being configured to convey the substrate to the heating element, the liquid storage portion being disposed at a first side of the assembly and an airflow channel at a second side of the assembly, the airflow channel defining an airflow path over the assembly and configured to convey the aerosol, and the power source being configured to supply power to the assembly.

A laminar heater with an electrically conductive laminar heating element having a pair of electrically conductive busbars disposed adjacent opposite ends of the heating element and at least a first area having a plurality of perforations with a generally polygonal geometry. Embodiments include those with Y-shaped perforations, including some with one prong diverging into a bulbous, optionally diamond-shaped, end, and those defined by an array of generally diamond shaped perforations intermeshed with an array of circular shaped perforations. Processes of manufacture and installation, heating systems including such heaters, and multi-ply embodiments having non-metal plies and an outer metal surface layer, are also disclosed.

A heater mat assembly for a rotor blade spar is provided including a plurality of electrically conductive heater wires extending in a spaced parallel configuration along a path of the rotor blade spar. An electrical current is flowed through the plurality of heater wires to inhibit ice accumulation on a portion of the rotor blade spar. At least one layer of a first insulating material is arranged adjacent a first side of each of the plurality of heater wires such that the at least one layer of the first insulating material is disposed between the plurality of heater wires and an adjacent surface of the rotor blade spar. The first insulating material comprises a thermally and electrically insulating material.

An aerosol-generating system including a cartridge is provided, the cartridge including a liquid storage portion including a housing configured to hold a liquid aerosol-forming substrate, the housing having an opening; and a heater assembly including at least one heater element fixed to the housing and extending across an opening of the housing, wherein a width of the at least one heater element of the heater assembly is smaller than a width of the opening of the housing. The heater element may be spaced from a periphery of the opening, leading to more efficient heating and aerosol production.

An electrical active unit (100) for generating a physical effect such as heat, cold or light emission, with a particular application to a temperature regulation system for regulating the temperature of a body, or to a light emission system to be worn by such a portion of a body. The electrical active unit (100) comprises a textile support (102) supporting: an active element (101) adapted for generating said physical effect; at least one electrical connection point (104) adapted to be connected to a power source and a controlling unit, and located on said active element (101); a sensor (106) adapted for being connected to the power source and the controlling unit, such that the electrical active unit may be connected to the power source and the controlling unit via the connection point in order to allow the powering of the active element by the power source and the activation/deactivation of said active element by the controlling unit depending on data sensed by the sensor. The textile support (102) has a first face and a second face opposite to said first face, the at least one connection point (104) being located solely on the first face, the active element (101) being embedded in the textile support (102) so as to form a determined pattern on the first and second faces. The pattern can avoid electrical current discharged from the connection points (104) through the second face, thereby avoiding direct contact between the skin and hot spots located at connection points (104).