Heaters having a body with having a top and bottom comprising pyrolytic boron nitride (PBN), a first heater electrode and a second heater electrode are described. The heater electrodes can be enclosed within an electrically insulating standoff and connected to separate busbars to provide power. Heater assemblies including one or more of the heaters and processing chambers including the heater assemblies are also described.

Provided is an aerosol generating device which is capable of stopping aerosol generation at an appropriate timing. This aerosol generating device includes a power source which supplies power in order to atomize an aerosol source and/or heat a flavor source; a sensor which outputs a measurement value for controlling the power supplied; and a circuitry which controls the power supplied from the power source on the basis of the measurement value. The circuitry controls to increase a power supply amount per unit time in response to a first condition that the measured value is equal to or larger than a first threshold being satisfied, and to decrease the power supply amount per unit time in response to a second condition that the measured value is less than a second threshold greater than the first threshold and a third condition which is different from the first condition and the second condition being satisfied.

Electric heating device and method for its manufacture An electric heating device a housing with a partition wall which separates a connection chamber from a heating chamber for dissipating heat and from which at least one PTC heating element with a heating element casing protrudes in the direction toward the heating chamber. At least one PTC element and conductor tracks, electrically connected in the connection chamber for energizing the PTC element with different polarities and connected to the PTC element in an electrically conductive manner, are supported in the heating element casing an insulated manner. For improved support of the PTC heating element, a holding element, engaging around the heating element casing, is connected to the partition wall on its side facing the heating chamber and is connected to the heating element casing. Also disclosed is a method for the manufacture of such an electric heating device.

A floor mat assembly for use on a floor comprises a floor mat, a first adhesive layer, a heating element, a second adhesive layer, and an insulative foam support layer. The floor mat comprises a topside for interaction with a person. The heating element is bonded to an underside of the floor mat with the first adhesive layer to heat the floor mat. The foam support layer is bonded to an underside of the heating element with the second adhesive layer.

An electrical heater and method for heating a catalyst. The heater includes a honeycomb body having intersecting walls forming channels extending along a longitudinal axis. A plurality of electrically resistive paths are included, each including at least a portion of the plurality of intersecting walls and extending a length across the honeycomb body transverse to the longitudinal axis. A positive electrode and a negative electrode are in electrical communication with each other via the resistive paths. The positive electrode and the negative electrode are operatively positioned to generate a respective flow of current through each resistive path. The lengths of at least two of the resistive paths differ from each other. The resistive paths are configured with respect to the at least one positive electrode and the at least one negative electrode such that the current in each of the resistive paths is substantially equal.

Systems, methods, and devices are disclosed. In an exemplary embodiment, a heating device for heating liquids in a reservoir, such as a tank or a container of a vehicle is disclosed. The heating device may have a housing which is resistant to the liquid to be heated and has a tubular outer casing closed at one end by a base part and at the other end by a cover part. The heating element may also include an insert inserted into the outer casing of the housing and at least one surface heating element arranged between the outer casing and the insert. Connecting conductors of the heating element may be routed out of the housing sealed, and at least one surface heating element may cover the inner surface of the outer casing, viewed in the circumferential direction of the outer casing, at least over a partial circumference, with which the outer casing may be in thermal contact, and the insert, or at least parts thereof, may be pretensioned and press the at least one surface heating element against the inner surface of the outer casing at least in partial regions.

A tankless water heater system (100), with a heat exchanger device (20) comprising at least one hollow chamber (21, 22, 23, 24 ) and at least one electrical heating element (52, 53, 54), and: a controller device (30) with a temperature control unit (35), a tap event counter unit (32), a down-time counter unit (33) and a time delay unit (34); an electrical switching element (41, 42, 43) for connecting or disconnecting one or several heating elements (52, 53, 54) to/from a power supply; an outlet temperature sensor (27) linked with the temperature control unit (35); a flow rate sensor (29); wherein: the tap counter unit (32) is connected to the flow rate sensor (29) and is triggered when water flow rate exceeds a tap indication threshold {dot over (V)}.sub.0 the down-time counter unit (33) is triggered and retriggered by the tap counter unit (32) and both provide a down-time event signal after any inactivity period with no water flow and records the duration of inactivity; the time delay unit (34) is connected to and triggered by the tap counter unit (32) starting a delay period t.sub.OFF which duration is switched from a short default delay period to a long delay period by the down-time signal provided by the down-time counter unit (33); and the switching elements (41, 42, 53) are triggered by the time delay unit (34) only after the delay period has elapsed.

A vaporizer device may include a controller and a heater control circuitry. The controller may generate, based at least on a temperature of a heating coil in a cartridge coupled with the vaporizer device, an output signal for controlling a discharge of a battery of the vaporizer device. The battery may be discharged to the heating coil to increase the temperature of the heating coil and cause a vaporization of a vaporizable material contained in the cartridge. The heater control circuitry may determine the temperature of the heating coil. The heater control circuitry may further control, based on the output signal from the controller, the discharge of the battery to the heating coil. The heater control circuitry may be powered by a voltage rail coupled to a voltage regulator configured to regulate an output voltage of the battery.

Features relating to a cartridge for use with a vaporizer body are provided. The cartridge mates with the vaporizer body in a cartridge receptacle. The cartridge may include a cartridge body defining a reservoir configured to contain vaporizable material; a mouthpiece coupled to a proximal end region of the cartridge body; at least one proximal absorbent pad wedged within an internal volume of the mouthpiece; a mouthpiece seal with sealing ribs; a cannula defining a vaporization chamber extending through the cartridge body; a resistive heating element; a porous wick configured to draw the vaporizable material in the reservoir towards the vaporization chamber; an internal sealing gasket positioned in a distal end region of the cartridge body; a lower support structure positioned in the distal end region of the cartridge body; and at least one distal absorbent pad configured to wedge within a recess located in the lower support structure.

A heat source comprised of one or more transistors or transistor packages mechanically connected to a heat plate. The heat generation is accomplished by the direct and precisely controlled heat generated by one or more transistors through the precise duty cycle control of a high-frequency Pulse-Width-Modulated (PWM) which is generated based on the sensed temperature and current generated by one or more of the transistor(s).