A glazing comprises first and second busbars for connection to an electrical supply; a third busbar between the first and second busbars; plural conductors electrically connected to the first busbar; wherein a first group of the conductors extends from the first busbar to the third busbar to form a first resistor; a second group of the conductors extends from a side of the third busbar facing the second busbar and is electrically connected to the second busbar to form a second resistor; fewer conductors extend from the side of the third busbar facing the second busbar than extend from a side of the third busbar facing the first busbar; at least one gap on one side of the third busbar opposite a conductor on the other side and an information acquisition area between the third busbar and the second busbar, the at least one gap being outside the information acquisition area.

A standoff assembly for use in terminating a plurality of resistive heaters disposed within a fluid vessel includes a pressure adapter plate, an electrical enclosure adapter plate, and a plurality of conduits. An end portion of each of the resistive heating elements extends through the pressure adapter plate. The electrical enclosure adapter plate is spaced apart from the pressure adapter plate to define a dry volume therebetween. The conduits are secured to the pressure adapter plate and the electrical enclosure adapter plate. Each conduit is aligned concentrically with each of the resistive heating elements. An electrical termination portion of each resistive heating element is disposed within the conduit.

An apparatus for heating a window of a vehicle comprises an electrical storage unit configured to store an electrical charge and a plurality of heating circuits disposed on a window of the vehicle. The apparatus further comprises a controller configured to monitor the electrical charge of the electrical storage unit and selectively activate one or more of the heating circuits based on the electrical charge.

A heating sheet and a battery module are provided. The battery module includes multiple battery cells and a heating sheet. The heating sheet includes multiple heating units and multiple connection units, and two adjacent heating units are coupled with each other through a connection unit. One heating unit may be attached to a side wall of one battery cell, and the connection unit corresponds to the gap region.

Electric heating system and heating method capable of adapting to various voltages are provided. The electric heating system includes: multiple heating elements, a controller, a variable-frequency charging element and at least one electric connector. The controller is electrically connected to the multiple heating elements arranged in parallel. The controller is electrically connected to the at least one electric connector through the variable-frequency charging element, allowing the electric connector to connect to power sources with different rated powers and delivers electricity to the multiple heating elements according to preset power-on logic. By adopting specific heating logic, the electric heating system and the heating method are applicable to various types of voltage inputs, independent temperature control for multiple pads is available, and adaption to all types of external power sources is enabled so as to ensure that 10 W, 18 W and 40 W external power sources can all operate at respective rated powers.

The present invention relates to methods and electro-thermal heating elements in which the electro-thermal heating element comprises a cut-out. Forming at least one multi-resistance patch for the cut-out and attaching the at least one multi-resistance patch to the electro-thermal heating element proximate to the cut-out.

An antenna has radio-frequency (RF) antenna elements and two substrates. A heater structure is connected to at least one of the two substrates, for heating the RF antenna elements. In one embodiment, the antenna comprises: a physical antenna aperture having an array of radio frequency (RF) antenna elements formed with patch and iris substrates, the iris substrate having a plurality of layers including an iris metal layer; and a heater structure coupled to one or more of the plurality of layers of the iris substrate for heating the RF antenna elements.

A method for establishing and/or maintaining a desired temperature of a material in an intermediate bulk container including the steps of positioning a heating element in at least partial contact with a material container containing the material within the intermediate bulk container; and applying an electrical power source to the heating element, wherein the heating element is at least partially made of a positive temperature coefficient resistant material, the heat from the heating element being largely transferred to the material in the material container.

An evaporator for an aerosol generating device is described. The evaporator comprises a heating body (101) comprising a plurality of channels (102) arranged through the heating body between an inlet surface (103) and an outlet surface (104). The channels are configured to transport liquid from the inlet surface through the heating body by capillary action. The heating body comprises electrically conductive material (120) and the evaporator further comprises circuitry (116) for providing a current through the electrically conductive material to provide resistive heating of the heating body to evaporate a liquid passing through the channels. The heating body and circuitry are configured to provide a positive temperature gradient across the heating body from the inlet surface to the outlet surface.

Examples disclosed herein relate to a to a pitch gradient in a lamp filament, and a method of making. In one implementation, a lamp has a bulb filled with a gas. A filament is disposed within the bulb. The filament has a plurality of coils that include a first coil having a first point. The plurality of coils includes a second coil having a second point, and a third coil having a third point. The pitch gradient is defined by a first pitch between the second point and the first point, and a second pitch between the third point and the second point. The second pitch is greater than the first pitch. The second point is 360 degrees away from the first point. The third point is 360 degrees from the second point. A terminal coil is electrically coupled to at least the first coil, the second coil, and the third coil.