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.

A PTC heating element comprises at least one PTC element and two conductor paths which are assigned to different polarities and which are electrically conductively connected to the PTC element and are provided with connection elements for the electrical connection of the PTC element. The PTC heating element has improved heat discharge due to the provision of an electromagnetic shielding which is formed from a fluid-permeable metal structure and which surrounds the PTC element and the conductor paths.

A PTC heating element has two insulating layers with a metallic coating provided on one side and a PTC element arranged therebetween. The PTC element is provided on oppositely disposed main side surfaces with a respective metallization which is electrically conductively connected to the coating of one of the insulating layers The metallization provided on one of the main side surfaces is assigned only to one potential for energizing the PTC element, and the metallization provided on the other of the main side surfaces is only assigned to the other potential for energizing the PTC element, as well as an electric heating device containing such a PTC heating element. With regard to better heat decoupling, the insulating layer may be glued to the PTC element, and the coating of the insulating layers is in direct electrically conductive contact with the metallization of the PTC element.

A fluid permeable heater assembly for aerosol-generating systems includes an electrically conductive flat filament arrangement and a first contact point and a second contact point for electrically contacting the flat filament arrangement. A longitudinal axis is defined between the first contact point and the second contact point. A center resistance Rc is the electrical resistance between two points situated on the longitudinal axis. One of the two points is situated at a distance from the first contact point equal to about 40 percent and the other one of the two points being situated at a distance from the first contact point equal to about 60 percent.

A heating device including a support and at least one heating element group on the support has at least one heating element on the support and two connection contacts for the heating element group. The two connection contacts are electrically disconnected from one another and make electrical contact with the single heating element or all of the heating elements of the heating element group for connection to a current supply or as a power connection. An effective width of all of the heating elements within a common heating element group is greater than an effective length of the single heating element or all of the heating elements of this common heating element group between the two connection contacts.

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 pressure-sensor-integrated glow plug which can increase reliability of a bonding portion between a ceramic heater and a metal-made outer sleeve while being manufactured with relatively simple manufacturing steps and, at the same time, can maintain airtightness over a long period, and a method of manufacturing such a pressure-sensor-integrated glow plug.

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.

The disclosure is and includes at least an apparatus, system and method for a flexible heater sensor suitable for association with a fluid bag. The apparatus, system and method may include a conformable substrate on a ply of the fluid bag opposite a printed flexible heater; and a matched function ink set, printed onto at least one substantially planar face of the substrate. The matched function ink set forms: at least one conductive layer capable of receiving current flow from at least one power source; and at least one dielectric layer capable of at least partially insulating and at least partially limiting conductivity of the at least one conductive layer; wherein the matched ink set is matched to preclude detrimental interactions between the printed inks of each of the at least one conductive and dielectric layers, and to preclude detrimental interactions with the conformable substrate; and wherein the at least one conductive layer and the at least one dielectric layer comprise a sensing circuit that senses at least the temperature of fluid within the fluid bag.

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.