An electrical heating assembly (1), in particular for use in a heatable seat device, comprises a plurality of heating wires (11, 12, 13, 14, 15) and a support structure (8) adapted to fix the heating wires (11, 12, 13, 14, 15). The heating wires (11, 12, 13, 14, 15) are arranged to form a plurality of hot points (10), a respective hot point (10) being defined by a circular area of 6 mm in diameter in which there are present at least three sections of heating wire (11, 12, 13, 14, 15) which are not interconnected to each other within the area of the hot point (10).

A multilayer structure for deicing an aircraft airfoil component includes an electrically and thermally insulating bottom layer formed in a defined pattern directly on the aircraft airfoil component, an electrothermal middle layer of electrically resistant heater element arrays formed in the defined pattern on the electrically and thermally insulating bottom layer, and a thermally conductive and electrically insulating top layer encapsulating the electrically and thermally insulating bottom layer and the electrothermal middle layer of electrically resistant heater element arrays. The multilayer structure may be directly applied to the airfoil component by direct writing/additive manufacturing, and may be done with the assistance of a multi-axis robot.

The grounded modular heated cover is disclosed with a first pliable outer layer and a second pliable outer layer, wherein the outer layers provide durable protection, an electrical heating element between the first and the second outer layers, the electrical heating element configured to convert electrical energy to heat energy, a heat spreading layer, and a thermal insulation layer positioned above the active electrical heating element. Beneficially, such a device provides radiant heat, weather isolation, temperature insulation, and solar heat absorption efficiently and cost effectively. The modular heated cover quickly and efficiently removes ice, snow, and frost from surfaces, and penetrates soil and other material to thaw the material to a suitable depth. A plurality of modular heated covers can be connected on a single 120 Volt circuit protected by a 20 Amp breaker. The modular heated covers are grounded for safety using the conductive heat spreading layer.

A heatable luminaire cover is described. The heatable luminaire cover has a polymeric main body, a first busbar, a second busbar and at least two conductor tracks on the inside of the polymeric main body.

The grounded modular heated cover is disclosed with a first pliable outer layer and a second pliable outer layer, wherein the outer layers provide durable protection, an electrical heating element between the first and the second outer layers, the electrical heating element configured to convert electrical energy to heat energy, a heat spreading layer, and a thermal insulation layer positioned above the active electrical heating element. Beneficially, such a device provides radiant heat, weather isolation, temperature insulation, and solar heat absorption efficiently and cost effectively. The modular heated cover quickly and efficiently removes ice, snow, and frost from surfaces, and penetrates soil and other material to thaw the material to a suitable depth. A plurality of modular heated covers can be connected on a single 120 Volt circuit protected by a 20 Amp breaker. The modular heated covers are grounded for safety using the conductive heat spreading layer.

A venting device for a battery system includes a venting part disposed on one surface of a case accommodating at least one battery cell and selectively forming a through-hole in the case, a gas sensor disposed inside or on one surface of the case and detecting at least one type of gas, and a temperature varying part varying a temperature of the venting part, wherein the venting part includes a melting member melted at a predetermined temperature or higher to form the through-hole.

An electrically heatable glazing panel including a substrate and at least a first electrically heatable zone including: (i) a substantially transparent, electrically conductive coating layer, (ii) at least first and second spaced bus bars substantially parallel and configured to supply electrical voltage across the substantially transparent, electrically conductive coating layer, and (iii) a conductive pathway defined between the at least the first and the second busbars. The glazing panel further includes a conductive pathway provided by a pattern of coated and decoated regions in the substantially transparent electrically conductive coating layer of electrically heatable zone to affect electrical resistivity of the coating in the first electrically heatable coated zone.

A transparent heater includes a plurality of high aspect ratio micro-wires. A plurality of channels is formed into the surface of a transparent substrate within an active heater region. The channels have a width of between 4 microns and 9 microns to insure that they are invisible to the naked eye, and a depth that is at least 1.5 times the width. Spacing between the channels is preferably at least 100 m. Micro-wires are formed by at least partially filling the channels with a conductive material. Power source connections are provided to connect to an electrical power source to supply a current through the plurality of micro-wires. An average optical transmittance of the transparent heater within the active heater region is greater than 50 percent.

A method for producing a heatable luminaire cover is described. The heatable luminaire cover has: a polymeric main body, a first busbar, a second busbar and at least two conductor tracks on the inside of the polymeric main body.

A coated graphite heater. The heater has a configuration comprising a plurality of heating elements having a major portion disposed parallel to an upper surface of the heater so that the major portion is disposed horizontally. The heater configuration provides a heater that exhibits reduced thermal stress and/or reduced CTE mismatch stress particularly compared to designs having heating elements with a major portion oriented perpendicular to the plane of the upper surface of the heater.