An electric heating module structure, an installation method, a forming method, and a wind turbine are provided. The electric heating module structure is configured for melting ice on a blade, and includes an electric heating module, a positive conductive wire and a negative conductive wire. The positive conductive wire and the negative conductive wire are integrally formed with the electric heating module, to supply power to the electric heating module. The integrally formed electric heating module, the positive conductive wire and the negative conductive wire are laid in an outer layer of the blade.

An electric heating module structure, an installation method, a forming method, and a wind turbine are provided. The electric heating module structure is configured for melting ice on a blade, and includes an electric heating module, a positive conductive wire and a negative conductive wire. The positive conductive wire and the negative conductive wire are integrally formed with the electric heating module, to supply power to the electric heating module. The integrally formed electric heating module, the positive conductive wire and the negative conductive wire are laid in an outer layer of the blade.

The present invention provides a conductive fabric comprising base cloth and a conductive metallic circuit structure formed on the surface of the base cloth. The conductive metallic circuit structure comprises at least one metallic seed layer and at least one chemical-plating layer. The metallic seed layer is an evaporation-deposition layer or a sputter-deposition layer and has a circuit pattern. The chemical-plating layer is applied over the surface of the metallic seed layer. The conductive fabric has improved conductivity and heat generation efficiency.

The present invention provides a conductive fabric comprising base cloth and a conductive metallic circuit structure formed on the surface of the base cloth. The conductive metallic circuit structure comprises at least one metallic seed layer and at least one chemical-plating layer. The metallic seed layer is an evaporation-deposition layer or a sputter-deposition layer and has a circuit pattern. The chemical-plating layer is applied over the surface of the metallic seed layer. The conductive fabric has improved conductivity and heat generation efficiency.

The invention relates to a heating structure (30) intended in particular for installation inside a passenger compartment of a vehicle, this structure being in particular a radiant panel, the heating structure (30) comprising at least one resistive layer arranged to give off heat when an electric current flows through this layer (31), this structure further comprising an array of electrodes (32) comprising a plurality of contact electrodes (33) that are arranged so as to be in electrical contact with the resistive layer in order to make electric current flow through this resistive layer, at least two of these contact electrodes being in contact with a region of the resistive layer (31), these two contact electrodes facing one another such that electric current can flow from one of these electrodes to the other of the contact electrodes by passing through this region of the resistive layer, these two contact electrodes (33) on either side of said region taking a shape chosen such that the two electrodes get closer to one another over a portion (38) of the electrodes and stay further away at the ends (39) of these electrodes.

A heater for an aerosol generating device includes a substrate and a plane heating element formed on one surface of the substrate, wherein the plane heating element includes an electrically conductive track pattern including a sensor seating region formed of a planar track on which an undersurface of a temperature sensor is configured to be seated.

A heater for an aerosol generating device includes a substrate and a plane heating element formed on one surface of the substrate, wherein the plane heating element includes an electrically conductive track pattern including a sensor seating region formed of a planar track on which an undersurface of a temperature sensor is configured to be seated.

A thin-film heater according to one or more embodiments may include an insulated substrate and metal wiring patterned thereon to extend between both terminals of the metal wiring. The metal wiring has a resistance of 10Ω or less between the terminals. The metal wiring includes a heat-generating layer made of a material that recrystallizes at a temperature of 200° C. or lower.

A thin-film heater according to one or more embodiments may include an insulated substrate and metal wiring patterned thereon to extend between both terminals of the metal wiring. The metal wiring has a resistance of 10Ω or less between the terminals. The metal wiring includes a heat-generating layer made of a material that recrystallizes at a temperature of 200° C. or lower.

A novel solid-state heating element is disclosed. The heating element comprises a plurality of heating layers comprised of a mixture of carbon and a polymer or plastic. The heating layers are disposed on or infused into a substrate. Each heating layer can be disposed on, or infused into, its own substrate, or the heating layers can be disposed on or infused into opposites sides of the same substrate. A radiating element can be disposed in proximity to one or both of the heating layers. The radiating element absorbs the radiation put out by the heating layer(s) and reradiates heat. A heat transfer fluid such as air or a liquid can be directed across the radiating element and/or other areas of the heating element to transfer heat from the heating element to another location.