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.

Disclosed in the present invention are a method and device for prolonging the service life of a ceramic electric heating body under a direct-current power supply condition. According to the solution, power can be supplied to a ceramic electric heating body in a forward-reverse inverting pulse manner under a direct-current condition, so that the service life of the ceramic electric heating body is prolonged. The beneficial technical effects of the present invention are: a method and device for prolonging the service life of a ceramic electric heating body under a direct-current power supply condition are provided; and the solution can effectively ameliorate the aging problem of a ceramic electric heating body, prolong the service life of the ceramic electric heating body, and ensure that the product performance is stable for a long time.

Vaporizer devices are disclosed that are configured to detect when a puff is occurring and exclude a pressure change unrelated to the puff based on at least first and second signals. Methods for detecting a puff and excluding a pressure change unrelated to the puff based on at least first and second signals are also disclosed.

A heater for heating an aerosol-forming substrate includes a plurality of elongate heating elements arranged in an elongate array. The elongate array has a support end with a first dimension, a heating end with a second dimension and a middle portion with a third dimension. The array is arranged to heat the substrate to form an aerosol. The third dimension is greater than the first dimension and greater than the second dimension. An electrically heated aerosol generating system can include the heater.

Vaporizer device features capable of improving on current approaches to mitigating against device damage or inoperability occurring from liquid exposure (e.g. exposure to liquid vaporizable material possibly affecting a pressure sensor, internal electronic circuitry, and/or electrical contact pins) are described.

A method of installing a heat shrink cover around a component includes providing an electrical heating system having an electrical heating unit and an electronic control unit connected to the electrical heating unit. The method includes attaching the electrical heating unit to an outer surface of the heat shrink cover, arranging the heat shrink cover around the component, retrieving a set-up parameter of the heat-shrink cover and/or the component, generating a set-up value indicative of the set-up parameter, and energizing the electrical heating unit to provide heat for heat-recovering the heat shrink cover. The energizing step is performed in response to the set-up value.

A specimen heating apparatus includes a heater unit configured to heat a test specimen held in a material testing machine, a heater holding unit configured to hold the heater unit in a set position relative to the test specimen for heating, a specimen temperature measurement unit attached to the heater unit and configured to measure temperature of the test specimen when the heater unit is in the set position, a temperature controller configured to control heating of the heater unit in response to a temperature measured by the specimen temperature measurement unit, and a thermal insulation unit configured to cover the heater unit, wherein the heater holding unit holds the heater unit in such a way that the heater unit is allowed to be brought to and removed from the set position while the test specimen is being held in the material testing machine.

A system and a method for controlling a power MOSFET for limiting electromagnetic interference from a load is provided. The system and method include a pulse-width-modulated (PWM) control voltage to operate the power MOSFET in accordance with its Ohmic region (linear mode). By operating the power MOSFET in its Ohmic region, the electromagnetic field generated by the load is reduced, without requiring a dedicated DC/DC converter that would otherwise increase the cost, size, and weight of the power electronics.

A method for heating an electrical bus in an electrical cabinet containing at least one current conversion device includes determining a temperature inside of the electrical cabinet. The method also includes determining a temperature outside of the electrical cabinet. Further, the method includes applying heat to the electrical bus via conduction when the temperature outside of the electrical cabinet is below a predetermined temperature threshold or a difference between the temperature inside of the electrical cabinet and the temperature outside of the electrical cabinet is less than a desired temperature difference.

Systems and methods for modulating power provided to a heating element of a vehicle exhaust system is provided. One system includes a controller controlling a switch, and an alternator having a first field terminal input, wherein the first field terminal input is connected to the switch. The system further includes a heating element connected to at least an output of the alternator. The controller is configured to determine a power demand for the electric heating element and modulate the first field terminal input to cause the alternator to provide power to the heating element according to the power demand.