The invention concerns a glazing comprising a first glass sheet having a surface; a printed layer on a part of the surface of the first glass sheet; a conductive coating on a part of the printed layer forming a coated print portion and on a part of the surface of the first glass sheet forming a coated glass portion; first and second busbars in electrical contact with the conductive coating and comprising a first or second busbar portion arranged on a different axis therefrom; a first printed layer portion adjacent the first or second busbar portion forming an adjustable coated print portion between the first and second busbars.

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.

The present invention relates to a heating device comprising: a base substrate; an electrically conductive layer, referred to as the heating layer, carried by the substrate, formed from at least one percolating network of nano-objects comprising metal nanowires; and a thermal diffusion layer made from aluminum nitride, covering all or part of the heating layer. The invention also concerns a method for preparing such a heating device.

The invention relates to a connection arrangement for an electrically conductive contact between at least one electrical conductor (17) provided on a screen (16), in particular for a motor vehicle, and an electrical coupling element (18), wherein at least one contact point (20) between the coupling element (18) and the electrical conductor (17) is provided on a coupling point (15) for the at least one electrical conductor (17) and wherein the electrical coupling element (18) and the electrical conductor (17) are connected to each other by means of an electrically conductive compound (19), and wherein the at least one contact point (20) of the coupling point (15) is at least partially surrounded by a casting compound (24), and a method for producing such a connection arrangement (10).

Methods of passively sampling PFAS in the environment, PFAS sorbents, apparatus and systems (apparatus plus conditions) for sampling groundwater, porewater, and surface water are described.

The present application relates to the technical field of smoking sets, and embodiments of the present application are a heating assembly and an electric heating smoking set. The heating assembly comprises: a heating tube comprising a tube body and a conductive part formed on the tube body; at least a base, the base being connected to the tube body; an insulating element provided between the base and the tube body; and a conductive element provided on the base and comprising a first part and a second part which are electrically connected to each other, wherein the first part is located between the insulating element and the tube body and makes contact with the conductive part to form electric connection, the second part deviates in the direction away from the tube body with respect to the first part, and the second part is used for being coupled with a power source.

Systems may include a heater including a plurality of heating elements that may include a first heating element configured to generate heat based on a first current, and a second heating element configured to generate heat based on a second current. Systems may further include an electromagnetic (EM) radiation reducing device configured to cancel electromagnetic emissions from the heater. The EM radiation reducing device may include a first EM radiation reduction element positioned adjacent to a first side of the heater, and a second EM radiation reduction element positioned adjacent to a second side of the heater, where the first and second EM radiation reduction elements have geometries configured based, at least in part, on the heater.

A multifunctional assembly having a resistive element a conductive element in electrical communication with the resistive element, the conductive element defining at least one of a plurality of multifunctional zones of the resistive element, wherein the conductive element is configured to direct a flow of electricity across at least one of the plurality of multifunctional zones of the resistive element in a preselected manner.

A heater 1a includes: a substrate 10 made of a resin; a conductive film 20 being a heating element; and a power supply electrode 30. The power supply electrode 30 is electrically connected to the conductive film 20 and is arranged along a surface of the conductive film 20. The power supply electrode 30 includes a conductive filler 30p and a binder 30m. The binder 30m binds the conductive filler 30p. The power supply electrode 30 has a specific resistance of 100 .Math.Ω•cm or less. The heater 1a satisfies a relation |Rd ― Ri|/Ri ≤ 0.2. Rd is an electrical resistance [Ω] of the heater 1a, the electrical resistance being obtained after an environment of the heater 1a is maintained at a temperature of 85° C. and a relative humidity of 85% for 1000 hours. Ri is an initial electrical resistance Ri of the heater 1a.

A film heater has a transparent conductive portion including: at least one non-conductive portion that has electrical insulation properties and extends in a direction intersecting a vibration direction of an electric field included in a radio wave transmitted from a radio wave transmitter-receiver; and a heat generator that generates heat by being energized and that transmits light. The film heater has: a first electrode connected to the heat generator; and a second electrode connected to the heat generator. The heat generator includes at least one conductive portion that is adjacent to the non-conductive portion and generates heat by a current flowing along a direction in which the non-conductive portion extends when the heat generator is energized by the first electrode and the second electrode.