A radiation heater apparatus has a plurality of heat radiation parts and a plurality of heating parts. A low thermal conductive part is formed between adjacent two of the heat radiation parts. The low thermal conductive part is provided with resin material which mainly forms a substrate part. The low thermal conductive part thermally isolates the heat radiation part by surrounding a periphery of the heat radiation part. As a body contacts with the surface of the apparatus, the thermal energy of specific heat radiation part directly under the body dissipates heat to the body. Furthermore, heat transfer from the periphery of the specific heat radiation part to the specific heat radiation part is reduced by the low thermal conductive part.

Power outputs in a heating control and/or regulation device are each electrically connectable to a heating element, especially a radiant heater. A power input is able to be connected electrically to a power supply for the heating elements. A power distribution device is connected electrically on its input side to the power input and is connected electrically on its output side via a branch to each of the power outputs to supply the power outputs with electric power from the power supply. A switching element is disposed in each of the branches or between each of the power outputs and the heating elements. A control and/or regulation unit is configured such that it controls and/or regulates the switching state of the switching elements as a function of set values. An interface receiving set values has at least one additional connection to a temperature measurement device that measures actual values of temperature. The control and/or regulation unit is configured such that it acquires the actual values of the temperature from the temperature measurement device and additionally controls and/or regulates the switching state of the switching elements as a function of these actual values of the temperature.

A device for emitting radiation includes a reflector component and a clip. The reflector component has a top side, a bottom side, and a perimeter side. At least one aperture formed within the reflector component that extends from a top opening on the top side of the reflector component through to a bottom opening on the bottom side of the reflector component. The clip may be connected to the reflector component and has a flat side that is in contact with the bottom side of the reflector component. Portions of the substantially flat side of the clip are configured to be soldered to a circuit board having an emitter which extends at least partially through the aperture when the clip is soldered to the circuit board.

A far infrared electrically and thermally conductive electrode device includes an electrode set and a connection assembly, through which the electrode set is connected to the case of a host in a wireless way. The electrode set is both electrically and thermally conductive. The method for making the electrode of the electrode device includes steps of disposing an electrode protecting layer on a first side of a far infrared heating layer; disposing an electrode insulating layer on a second side of the far infrared heating layer; disposing an electrode layer on the surface of the electrode insulating layer; and covering the electrode layer with a conducting gel layer. Through the above-mentioned structure, the electrode set emits far infrared rays and generates heat when the host supplies power. The electrode set becomes conductive to simulate nerves of different layers of tissue under a person's skin.

A heating device may include a substrate and a heating element disposed on a surface of the substrate. The heating element may include an ohmically resistive coating having a layer thickness of 2 to 300 microns. The ohmically resistive coating may include at least 30% by weight of at least one ductile or malleable metal and a plurality of electrically resistive particles. The ohmically resistive coating may be deposited via the at least one of the cold spray and the solid state deposition performed at a temperature below at least one of a melting temperature and a partially softening temperature of the at least one ductile or malleable metal. The ohmically resistive coating may exhibit less heterogeneity and porosity than a thermally sprayed coating, may have a density of 90% or greater, and may have a porosity of 10% or less.

A mobile device for heating a rail (12) of a railroad (2) is made up of a heating module (34) comprising at least one heating zone (28) and at least one radiating heat source (46) directed towards the heating zone (28), and of a transport vehicle (16) for transporting the heating module (34). A heating unit (36) of the heating module (34) comprises infrared-radiation electric lamps (42) able to emit radiation that is concentrated in the near-infrared, and which are equipped with a primary reflector (48) oriented in such a way as to reflect the infrared radiation emitted by the radiation source (46) towards the heating zone (28). The heating unit (36) also comprises a secondary reflector (50) having a concave reflective surface surrounding the heating zone (28) and able to return towards the heating zone (28) rays reflected by the rail and that pass between the infrared-radiation electric lamps (42).

The present invention provides an infrared sauna room with a low electric field and low electromagnetic wave radiation comprising a room body, heating plates with a low electric field and low electromagnetic wave radiation and shielding lines, wherein a plurality of heating plates with a low electric field and low electromagnetic wave radiation are distributed in the room body; the first insulating layer has concave points or/and convex points; and the shielding line comprises a stranded power wire, an electric field absorbing shielding layer and a wire insulating layer. Through the above-mentioned manner, the infrared sauna room with a low electric field and low electromagnetic wave radiation can significantly reduce electromagnetic wave radiation and electric field radiation for sauna rooms.

A ceramic reflector (100) for at least one IR lamp comprises at least one elongated concave reflector body (102). Each of the at least one elongated concave reflector bodies comprises an elongated bottom section and two elongated upstanding walls. Each of the elongated concave reflector bodies is provided for containing at least one IR lamp (150) and for reflecting the IR light from the at least one IR lamp. Each elongated concave reflector body has in each cross section at both of its upstanding walls a wall height. The wall height is the vertical distance between the deepest level of the bottom section of the reflector body and the highest level of the upstanding wall. At one or at both longitudinal ends of at least one reflector body; the wall height is at both upstanding walls larger than in the middle section of the elongated concave reflector body.

A radiant panel (1) intended to be installed inside a vehicle (80) passenger compartment (3), in particular a motor vehicle passenger compartment, the radiant panel (1) comprising at least one array of electrodes with at least two primary electrodes of different polarities, the array of electrodes being arranged such that at least two primary electrodes of different polarities each define at least one spiral winding around one another.

A temperature control system for controlling the temperature of a room and a composite element for a temperature control system.