The present invention relates to a heating device for an aircraft interior. The heating device has a mechanically loadable support structure, a mechanically loadable and thermally conductive outer structure, and a heater for converting electrical energy into thermal energy, wherein the heater is arranged between the support structure and the outer structure and has a heating layer composed of a resistance material with a positive temperature coefficient.

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.

The invention relates to a device for supporting and fastening heating pipes (20) of a heating system placed in subfloors, walls or ceilings of a building. The device comprises: a laminar body having a first face and an opposite second face, a plurality of fastening elements made in one piece on the first face of the laminar body and configured to fasten said heating pipes on the first face. The invention is characterized in that both the laminar body and the fastening elements of the device are in a mixture comprising at least one thermoplastic polymer and thermally conductive inorganic fillers.

An attachment part for a motor vehicle includes a main body and a securing element where the attachment part is mechanically securable to the motor vehicle by the securing element. An electrical consumer is integrated into the attachment part. Connection conductor tracks are attached to the main body, contact the electrical consumer, and extend as far as the securing element where the electrical consumer is electrically connectable to a power supply on the motor vehicle by the connection conductor tracks.

A heating tile designed to be easily installed using standard construction methods and materials while providing a radiant heating method that is compatible with both computer controlled systems as well as simple thermostat controls, can be repaired without major floor rework, does not produce a significant magnetic field, is protected against overheating due to excessive exposed surface insulation, and is water and contaminant resistant even if there is minor cracking of the tile.

A system and method for heating concrete structures to either prevent the build-up of freezing precipitation or eliminate freezing precipitation on a top surface of the concrete structures. The system includes a heating assembly integrally formed with a concrete structure to apply thermal energy to the top surface of the concrete structure. Optionally, the heating assembly includes heating elements formed of carbon fiber tape. Following formation of the concrete structure, the heating assembly is configured for unified movement with the concrete structure. The system optionally includes a control assembly operatively coupled to the heating assembly. The control assembly selectively powers the heating assembly and can be configured for remote operation. In use, the control assembly can be selectively activated from a remote location to power the heating assembly and heat the concrete structure.

A system and method for heating concrete structures to either prevent the build-up of freezing precipitation or eliminate freezing precipitation on a top surface of the concrete structures. The system includes a heating assembly integrally formed with a concrete structure to apply thermal energy to the top surface of the concrete structure. Optionally, the heating assembly includes heating elements formed of carbon fiber tape. Following formation of the concrete structure, the heating assembly is configured for unified movement with the concrete structure. The system optionally includes a control assembly operatively coupled to the heating assembly. The control assembly selectively powers the heating assembly and can be configured for remote operation. In use, the control assembly can be selectively activated from a remote location to power the heating assembly and heat the concrete structure.

Provided is a self-heated enclosure with carbon fiber. An example system can comprise an enclosure defining an interior chamber. The system can comprise at least one electrically conductive carbon fiber member configured in relation to the enclosure to provide a thermal output to the interior chamber when a voltage is applied to the at least one electrically conductive carbon fiber member. The system can further comprise a power source electrically coupled to the at least one electrically conductive carbon fiber member. The power source can be configured to selectively apply the voltage to the at least one electrically conductive carbon fiber member.

Provided is a self-heated enclosure with carbon fiber. An example system can comprise an enclosure defining an interior chamber. The system can comprise at least one electrically conductive carbon fiber member configured in relation to the enclosure to provide a thermal output to the interior chamber when a voltage is applied to the at least one electrically conductive carbon fiber member. The system can further comprise a power source electrically coupled to the at least one electrically conductive carbon fiber member. The power source can be configured to selectively apply the voltage to the at least one electrically conductive carbon fiber member.

There is provided an electric suspended radiant disk heater apparatus comprising: a central and vertical ceiling mount pole for hanging from a ceiling at an upper end thereof in use; a radiant heater disk element fastened at a lower end thereof, the radiant heater disk element being substantially co-axial with the ceiling mount pole, being substantially perpendicular to the ceiling mount pole and extending radially from the lower end of the pole; and an electric heater element thermally coupled to the radiant heater disk element to heat the radiant heater disk to radiate heat from a radiant heat emitting undersurface thereof.