A system and method for controlling power includes a power source, a plurality of primary control circuits, a load, at least one secondary control circuit, a switch circuit, and a control channel. The plurality of primary control circuits are connected to control load power from the power source to respective ones of a plurality of load power inputs. The load is configured to receive power from the plurality of load power inputs. The at least one secondary control circuit is connected to the power source, and the switch circuit is connected between the at least one secondary control circuit and the plurality of load power inputs. The control channel is configured to control the switch circuit to connect the at least one secondary control circuit to a selected one of the plurality of load power inputs.

Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

A heatable laminated vehicle window for separating a vehicle interior from an outer surrounding area is presented. The vehicle window includes an outer pane bonded to an inner pane via a thermoplastic intermediate layer. An electrically heatable coating of the vehicle window is electrically connected to two busbars such that by applying a supply voltage across the two bus bars, a heating current that forms heating field flows between the two busbars. In one aspect, a metal element is arranged on or in the vehicle window such that heat is dissipated out of a region of the heating field that has elevated heat generation by means of thermal conduction of the metal element.

An electrical heating device comprises: a first electrode layer (13), made of electrically conductive material; a second electrode layer (14), made of electrically conductive material; and a heating layer, made of a material having a PTC effect, wherein the first electrode layer (13) and the second electrode layer (14) face one another, with at least one part of the heating layer that is set between the first electrode layer (13) and the second electrode layer (14), in contact with them. At least one region (21) of the at least one from among the first electrode layer (13), the second electrode layer (14), and said at least one part of the heating layer has a plurality of electrically non-conductive sites (30a, 30b, 30c), which are prearranged for bringing about: an emission of heat by the heating device (10) in said at least one region (21) that is different from the emission of heat by the heating device (10) in at least one other region (22) of the at least one from among the first electrode layer (13), the second electrode layer (14), and said at least one part (15) of the heating layer (15); and/or an emission of heat by the heating device (10) at the first electrode layer (13) that is different from the emission of heat by the heating device (10) at the second electrode layer (14).

A substrate support for a substrate processing system includes a plurality of heating zones, a baseplate, a heating layer arranged on the baseplate, a ceramic layer arranged on the heating layer, and wiring provided through the baseplate, the heating layer, and into the ceramic layer in a first zone of the plurality of heating zones. An electrical connection is routed from the wiring in the first zone, across the ceramic layer to a second zone of the plurality of heating zones, and to a heating element in the heating layer in the second zone.

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).

Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

A heating mechanism for atomization by heating and an atomization device, the heating mechanism comprising heating circuits for evaporating liquid and electrodes for connecting to a power supply unit. All of the heating circuits are connected in parallel between contacts of two electrodes, two adjacent heating circuits are connected by a plurality of connections to form a planar integrated unit, and heat dissipation members extending laterally for dispersing heat from the heating circuits are provided in at least the intermediate of the outer heating circuits. The atomization device comprises a porous ceramic body and the heating mechanism, wherein the heating mechanism is embedded in and planarly attached to the bottom of the porous ceramic body. The heating mechanism has a good support strength and provide uniform heat distribution, the heating mechanism of the atomization device is not separated from the ceramic body and has a good heating uniformity.

A series of heated control sticks for rotorcrafts, tiltrotors, and helicopters. The heated collective and cyclic sticks feature several heater assemblies to provide localized heating for pilots and co-pilots. The heater assemblies are formed from several layers of fabrics and resistive materials designed to generate heat while current is provided to conductive materials in the resistive material. A controller provides individualized control for users to adjust the temperature of various zones associated with either the collective stick or the cyclic stick. The heater assemblies can be installed entirely external to the stick like in a retrofit or partially internally.

A heating device has a support and a heating element arranged on it, the heating element having two electrical terminals and a multiplicity of heating conductors that are electrically connected to one another. Starting from the one terminal, the heating element is divided into a number of heating conductors parallel to one another and in series one behind the other toward the second terminal. In this case, at least three heating conductors are connected in parallel next to one another and at least three heating conductors are connected in series one behind the other. Series-connected heating conductor groups can be formed, heating conductors being parallel within a heating conductor group.