The present disclosure relates to a control method of an aerosol generating device. The control method includes the following steps. In step S100, the aerosol generating device is powered on. In step S200, the aerosol generating device displays a plurality of preset smoking modes and an option of establishing a new smoking mode. In step S300, when a user selects a preset smoking mode, step S400 is executed. In step S400, when the user chooses to execute the preset smoking mode, step S520 is executed. In step S520, the aerosol generating device works in the smoking mode when the user inhales.

An electronic cigarette and temperature control method thereof are provided. The temperature control method of the electronic cigarette includes: identifying type of tobacco liquid in the electronic cigarette; acquiring preset temperature information corresponding to the type of the tobacco liquid; and controlling the electronic cigarette to work according to the acquired preset temperature information. The method of the present disclosure could adjust the temperature of the electronic cigarette automatically to meet user's need, which could simplify operation and improve the user experience.

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.

The present application is disclosed an atomizing component and an electronic cigarette. The atomizing component comprises a light-permeable e-liquid storage sleeve. An atomizing core is detachably connected to an end of the e-liquid storage sleeve. A fastening element for restricting radial expansion of the e-liquid storage sleeve is sleeved at where the e-liquid storage sleeve is insertedly connected to the atomizing core. An end of a ventilation pipe opposite to the atomizing core is a smoke emitting outlet in communication with a suction nozzle. An e-liquid filler hole is extended from the end of the ventilation pipe provided with the smoke emitting outlet. The smoke emitting outlet and the e-liquid filler hole are located on planes of different heights; while e-liquid is being added, the outer circumferential wall of the ventilation pipe blocks the e-liquid splashed accidentally, thus preventing the e-liquid from being splashed into the ventilation pipe.

An electronic vaping device includes a cartomizer and a battery section. The cartomizer includes a housing, a liquid supply reservoir in the housing, a vaporizer connected to the liquid supply reservoir, a channel adjacent to the liquid supply reservoir. The liquid supply reservoir being is to store vapor precursor. The vaporizer includes a fluid-transport structure that is configured to transport the vapor precursor from the liquid supply reservoir to the channel. The battery section is configured to provide power to the vaporizer. The battery section includes a control circuit that is configured to determine a saturation level of the vapor precursor on the fluid-transport structure based on an electrical resistance of the fluid-transport structure.

A removable heater assembly for an aerosol-generating device is provided, the removable heater assembly being configured to heat a tobacco plug and including an electrical heater, a data storage device, and data stored on the data storage device, the data including calibration data for the electrical heater. An aerosol-generating device is also provided, including the removable heater assembly, a housing defining a cavity configured to removably receive the removable heater assembly and an aerosol-generating article, a power supply, and a controller configured to receive data from the data storage device of the removable heater assembly and to control a supply of electrical power from the power supply to the electrical heater of the removable heater assembly based on the received data.

A power supply unit for an aerosol generation device includes an internal power supply configured to hold power supplied to a heater configured to heat an aerosol source, a first connector connectable to an external device and including a first communication terminal, a controller configured to control power supply from the internal power supply to the heater and including a second communication terminal, a first communication path between the first communication terminal of the first connector and the second communication terminal of the controller, and a switch unit positioned on the first communication path and configured to set the first communication path to a conductive state or a disconnected state.

The method includes first defining a reservoir in a housing, the reservoir configured to contain a non-nicotine pre-vapor formulation, the non-nicotine pre-vapor formulation being devoid of nicotine and including at least one non-nicotine compound, positioning a heater and a wick in a chamber, the heater being in heating proximity to the wick, second defining at least one first channel, the at least one first channel being configured to communicate the non-nicotine pre-vapor formulation from the reservoir to the wick, and third defining at least one first air passage, the at least one first air passage being configured to allow air to enter the reservoir.

An electronic smoking apparatus (100) comprising control circuitry (126), driving circuitry (122), charging circuitry (124), excitation element (128), a flavoured source (112) and a battery (114), the electronic smoking apparatus (100) being operable in a smoking mode or a charging mode; wherein excitation signals are to flow from the battery (114) to the excitation element (128) through a first switchable conductive path and in a first conduction direction when the electronic smoking apparatus (100) operates in the smoking mode, and charging current is to flow from an external charging power source to the battery (114) through a second switchable conductive path and in a second conduction direction when the electronic smoking apparatus (100) operates in the charging mode, the second conduction direction being opposite to the first conduction direction; and wherein the second switchable conductive path forms a portion of the first switchable conductive path.

The present invention relates to vaporizer heating assemblies for electronic cigarettes. In certain embodiments, vaporizer heating assemblies include: heating assembly and electric conductor assembly. Heating assembly includes: heating assembly covers, round heating element mounting base, heating elements, and e-liquid media. Heating elements have heating wires formed in a large surface to ensure sufficient vaporization of e-liquid. Heating assembly covers define certain e-liquid conduit openings to allow the e-liquid to flow from outside of the heating assembly covers into the e-liquid media. The heating elements are in direct contact with the e-liquid media to generate large amount of vapor for its user. Electric conductor assembly includes: an electric connector base for a first terminal of heating elements, an electrode for a second terminal of heating elements, and an insulation cover to insulate the electric connector base and the electrode. Electric conductor assembly is positioned in a lower portion of heating assembly.