A radiating panel includes the following succession of layers: at least one supporting layer which is at least thermally insulating and constituted by a material chosen from extruded expanded polystyrene, sintered expanded polystyrene, and polyisocyanurate; at least one heating layer which includes at least one electric heating element and a studded element with interspaces for laying at least one electric heating cable. The studded element has a shaped sheet element with studs extending in the opposite direction to that of the supporting layer.

The panel includes at least one finishing layer which is at least thermally conducting and made of a material chosen at least from ceramic and natural stone.

The panel also includes an adhesive between the heating and finishing layers, and the studded element is coupled to the supporting layer using one element chosen from glue, extruded adhesives, silicone glues, pressure-sensitive adhesive systems, and mechanical fixing elements.

Disclosed is a heating device, including a housing, and an electrothermal film and a fan arranged in the housing, wherein the fan is located at a bottom of the electrothermal film, the fan is provided with an air inlet facing upwards and an air outlet facing forwards, and the housing is provided with a vent hole at a position corresponding to the air outlet.

A heating apparatus including a storage device and at least one heater member. The heater member can be connected to the storage device and an electric power supply source. An inverter is connected to the output of the storage device and the electrical supply source. First switching elements are used to vary the first connection elements between an open circuit configuration and a closed circuit configuration in which electrical energy stored in the storage device is injected into the electrical supply source via the inverter.

A radiant heater is disclosed. The radiant heater includes a heating layer, with a first elongated conductor configured to receive electricity and a second elongated conductor disposed parallel to the first conductor. A continuous sheet of resistive material adapted to produce heat in response to electrical current is disposed between the first and second elongated conductor. The heater also includes a transparent layer and a non-transparent functional layer that is disposed between the heating layer and the transparent layer. In a preferred aspect, the invention is in the form of a heating mirror.

A method of managing a combi radiator (1), the method comprising the following steps that are repeated for each current day, and for each current period taken from a predetermined set constituted by at least one successive period defined in the current day:

acquiring a predetermined indication from a predefined table (30), said predetermined indication being associated with said current period and being taken from a list comprising a first indication for which only the electrical radiator system (2) is to be activated, and/or a second indication for which only the hot-water radiator system (3) is to be activated, and/or a third indication for which both the electrical radiator system and the hot-water radiator system are to be activated;

controlling the radiator as a function of the predetermined indication.

Disclosed is a heating device, including a housing, and an electrothermal film and a fan arranged in the housing, wherein the fan is located at a bottom of the electrothermal film, the fan is provided with an air inlet facing upwards and an air outlet facing forwards, and the housing is provided with a vent hole at a position corresponding to the air outlet.