A temperature manipulating apparatus for providing heating to different components of a vehicle, which includes a base medium made of rigid or flexible materials, such as glass, ceramic, plastic sheet, a fabric sheet and a leather sheet. The temperature manipulating apparatus includes a plurality of heat generating elements which are connected to the plurality of electricity conducting electrodes. The temperature manipulating apparatus includes a plurality of electricity conducting electrodes which are disposed on the heat generating elements and the base medium. The temperature manipulating apparatus may be supplied electricity from an electric power source via a connecting module. The plurality of heat generating elements may be in form of one or more layers of electrically conductive elements disposed on the base medium. The heat generating elements may be arranged in various configurations with respect to the electricity conducting electrodes to maximize the heating effect and suit different shapes of different components to be applied with the temperature manipulating apparatus.

Resistive heating assemblies comprising a substrate, a conductive coating comprising graphenic carbon particles applied to at least a portion of the substrate, and a source of electrical current connected to the conductive coating are disclosed. Conductive coatings comprising graphenic carbon particles having a thickness of less than 100 microns and an electrical conductivity of greater than 10,000 S/m are also disclosed.

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.

A heating appliance includes a housing having interior walls with interior surfaces defining a cooking chamber for heating food, a microwave heating source configured to generate microwave radiation for heating the food, and a thermoresistive heating plate disposed in an opening defined in an interior wall. The thermoresistive heating plate has a substrate having an inner surface aligned with the interior surface of the interior wall, and a bottom surface opposite to the inner surface. The thermoresistive heating plate includes a thermoresistive coating disposed on the bottom surface configured to generate heat upon application of an electric current such that the heat is transmitted through the substrate to the cooking chamber from the thermoresistive coating, the microwave heating source, or both, and the substrate is transparent to microwave radiation to allow microwave emission through the substrate.

An induction coil and method for heating susceptors within a portion of a living body, include an effective diameter that is determined based on a cross-sectional area of the induction coil, a length determined along an axis of the induction coil that is orthogonal to the cross-sectional area, and a ratio of the length to the effective diameter that ranges between 0.25 and 0.75, such that a magnetic field is generated that ranges between 1 kA/m and 40 kA/m with an input frequency that ranges between 50 kHz and 1 MHz

An electrically heatable layer stack is disclosed. The electrically heatable layer stack includes at least two substrate layers, and at least one carbon nanotubes-, CNT-, layer, which is arranged between the substrate layers and which is configured to conduct an electric current. The substrate layers and the at least one CNT-layer are configured to produce heating of at least one of the substrate layers when an electric current is applied to the at least one CNT-layer. A vehicle assembly group, an aircraft, a method and a system for manufacturing an electrically heatable layer stack are also disclosed.

A method of tuning an electrical resistance of a laser-induced graphene heater is provided. The method includes forming a base carbon heating element, and determining a target electrical resistance of a laser-induced graphene (LIG) heater to be fabricated from the base carbon heating element. The method further includes determining a targeted LIG pattern that provides the target electrical resistance, and directing laser energy on to the base carbon heating element based on the targeted LIG pattern to form one or more LIG regions. The one or more LIG regions define a LIG pattern to from the LIG heater having the target electrical resistance.

The invention concerns a transparent heating device comprising: a graphene film fixed to a transparent substrate; a first electrode (205) connected to a first edge of the graphene film; and a second electrode (206) connected to a second edge of the graphene film, wherein there is a resistance gradient across the graphene film from the first electrode (205) to the second electrode (206).

Apparatus, materials, and techniques and techniques herein can include providing a deposited layer comprising a composite material including carbon nanotubes (CNTs). According to various examples, the composite can be applied to a substrate such as using a solution containing CNTs and other constituents such as sulfur. The solution can be spray-applied to a substrate, or spin-coated upon a substrate, such as to provide a uniform, conductive, and optically-transparent film layer. In one application, such a film layer can be clad or otherwise assembled in a stack-up including a substrate and cover layer (e.g., glass layers), such as to provide a transparent assembly. Such an assembly can include a portion of a window, such as a windscreen for a vehicle, where the CNT material can provide a conduction medium for Joule heating.

There are provided a transparent conductive film, as well as a heater, a touch panel, a solar battery, an organic EL device, a liquid crystal device, and an electronic paper that are provided with the transparent conductive film, the transparent conductive film being capable of easing a decline in optical transmittance when graphene is laminated, and of achieving optical transmittance higher than an upper limit of optical transmittance of a single layer of graphene. The transparent conductive film includes a single-layered conductive graphene sheet. The single-layered conductive graphene sheet includes a first region and a second region, the first region being configured of graphene, and the second region being surrounded by the first region and having optical transmittance that is higher than optical transmittance of the first region.