The heater device has a sheet shaped main body having a heat generating portion heated by energization and a radiating surface for radiating radiant heat toward a heating object by using heat in the heat generating portion, a plate shaped member arranged on an opposite side with respect to the radiating surface of the main body, and an air layer forming member for forming an air layer between the main body and the plate shaped member arranged on a side opposite to the radiating surface of the main body.

The present invention relates to a vehicle radiation heater being configured to perform heating by directly emitting radiant heat toward a passenger at an early stage of starting of a vehicle in winter. The vehicle radiation heater according to the present invention can be simple in structure, thereby being easy to manufacture, can quickly emit high-temperature radiant heat over the entire area of the heater, thereby enhancing rapid and comforting heating effects, and can maintain a constant temperature, thereby preventing a risk of overheating.

The invention relates to an air conditioning system for a vehicle, in particular an electric vehicle, comprising at least one active heating and/or cooling device, at least one passive heating and/or cooling device, and a control unit for controlling the at least one active and the at least one passive heating and/or cooling device, wherein the at least one active and the at least one passive heating and/or cooling device each comprises a nanomaterial, the at least one passive heating and/or cooling device comprises a thermal conductor element, which is thermally coupling at least one electronic device, in particular a display, to an outside air stream, the at least one active heating and/or cooling device comprises a nanoparticle containing resistive heating element for actively heating and/or the nanomaterial of the at least one cooling device is brought into contact with a cooling fluid in addition to an outside air stream for actively cooling, and the control unit is adapted to control the at least one active and the at least one passive heating and/or cooling device depending on an input from at least one sensor, in particular a temperature sensor, and/or depending on at least one user input.

The invention further relates to a vehicle with such an air conditioning system (10).

The heater device is provided with a heater main body, and radiates radiant heat from the heater main body toward an object. The heater main body includes a sheet-like heat generating layer that generates heat and radiates the radiant heat, and a sheet-like heat insulating layer that is disposed on the side opposite to the object of the heat generating layer. The heat insulating layer has a sheet-like first layer having voids and a sheet-like second layer having voids arranged side by side in a thickness direction of the heat insulating layer with respect to the first layer. A porosity of the second layer is higher than that of the first layer.

There is provided a door trim including: an armrest; an ornament member coupled to the armrest; and a planar heater configured to warm the armrest or the ornament member. The planar heater is disposed between a resin core member and a surface member which form the armrest or the ornament member, and includes a nonwoven fabric and a heating wire fixed to the nonwoven fabric. The nonwoven fabric includes first and second bonded parts and a connection part connecting between the first and second bonded parts. The second bonded part is routed to be disposed on the back surface side of the armrest (the back surface side of the ornament member) by the connection part being inserted into an interface gap between the armrest and the ornament member. A thermostat is mounted on the second bonded part.

Heating element for user-touchable areas in a vehicle with a foamed carrier material in which at least one heating conductor, which comprises an electrical insulation, is embedded, and with connecting conductors which are electrically connected to the ends of the heating conductor via at least one connection part and form an electrical feed line. The at least one connection part is arranged within the foamed carrier material and the connection part is foam-covered in an electrically insulating manner by the carrier material. The connection part is brought into electrically conductive contact at least partially with the respective connection end of the heating conductor due to applied pressure and/or applied heat, at least partially destroying the electrical insulation in the region of the connection part. Furthermore, a method for producing such a heating element using a mold tool is indicated.

The present disclosure generally relates to providing climate control within a vehicle. More particularly, the present disclosure relates to using an infrared (IR) heating module having one or more IR panels installed within a roof of a passenger cabin, the IR panel(s) configured to radiate heat to passengers within the vehicle at a low power. Vehicles having the IR heating module installed with various IR panel configurations within the roof are also provided. In addition, programs and instructions embodied within a computer or software program stored on a non-transitory machine-readable medium and executed by the controller of the IR heating module are provided.

A heater device includes a contact determination unit for determining contact or non-contact of an object based on a change in capacitance between a plurality of electrodes. The contact determination unit is configured to determine (i) the contact of the object in response to a determination that the change in capacitance between the plurality of electrodes per predetermined unit time is a change in one direction and equal to or larger than a first determination threshold value. The contact determination unit is configured to determine (ii) the non-contact of the object in response to a determination that the change in capacitance between the plurality of electrodes per predetermined unit time is a change in a direction opposite to the one direction and equal to or larger than a second determination threshold value.

An electrode carrier of a vehicle heating device applying a CNT composite material includes a first electrode part and a second electrode part having different polarities from each other and formed in a straight line along a length direction of a vehicle; a fixing member configured to fix the first electrode part and the second electrode part to the vehicle; and the CNT composite material formed between the first electrode part and the second electrode part, configured to generate heat when being electrified, and fixed to the vehicle.

An infrared warmer device may include a touch sensor unit including a detecting wire mounted adjacent to a heating layer; a temperature sensor unit mounted adjacent to the heating layer; a cover covering the heating layer, an electrode unit, the touch sensor unit, and a temperature sensor unit; and a control unit controlling an amount of electric power supplied through the electrode unit such that a temperature detected by the temperature sensor unit reaches a target temperature, and changing the target temperature to a safe temperature when a touch of a body is detected through the touch sensor unit.