A system includes a converter configured to electrically couple to a power source and to a heating element of a vaporizer atomizer. The converter can be further configured to receive a first voltage from the power source and provide a second voltage to the heating element. The converter can be a direct-current to direct-current converter. A power monitor configured to electrically couple to the heating element, measure a current through the heating element, measure a voltage over the heating element, calculate a power and/or resistance, and output a control signal to the converter. The converter can be configured to be controlled by the control signal to vary the second voltage to maintain a target power or a target temperature over the heating element. Related apparatus, systems, techniques and articles are also described.

An aerosol-generating device comprises an infrared emitter and an electric core for supplying power to the infrared emitter; the infrared emitter comprises at least one first infrared emission region and at least one second infrared emission region arranged in sequence along the circumferential direction of the chamber; the first infrared emission region and the second infrared emission region are independently activatable to independently radiate infrared rays into the chamber to heat different portions of the smokable material. In the above aerosol-generating device, the regions of the smokable material receiving chamber which are different along the circumferential direction correspond to the first infrared emission region and the second infrared emission region, respectively, and can be independently heated by the first infrared emission region and the second infrared emission region, respectively, in use, so that the smokable material can be gradually heated from part to whole in use.

A hybrid aerosol-generating device contains a HNB article and an ECIG article. The hybrid aerosol-generating device allows for simultaneous inhalation from both a HNB article and an ECIG article. The hybrid device includes a HNB article configured to heat non-liquid materials without combustion of the non-liquid materials and also includes an ECIG article configured to heat liquid materials without combustion of the liquid materials. The hybrid aerosol-generating device may further include a mouthpiece connected to both the HNB article and the ECIG article to allow for the simultaneous delivery of aerosols and/or vapors created by the heated non-liquid materials and the heated liquid materials.

A hybrid aerosol-generating device contains a HNB article and an ECIG article. The hybrid aerosol-generating device allows for simultaneous inhalation from both a HNB article and an ECIG article. The hybrid device includes a HNB article configured to heat non-liquid materials without combustion of the non-liquid materials and also includes an ECIG article configured to heat liquid materials without combustion of the liquid materials. The hybrid aerosol-generating device may further include a mouthpiece connected to both the HNB article and the ECIG article to allow for the simultaneous delivery of aerosols and/or vapors created by the heated non-liquid materials and the heated liquid materials.

An aerosol generation device comprises a chamber, a housing and a cover. The chamber is adapted to receive a consumable. The housing contains the chamber and comprises an opening through which the consumable can be removed from the chamber. The cover is configured to move between an open position where the opening of the housing is exposed and a closed position where the opening of the housing is closed. The aerosol generation device is adapted to generate an inhalable vapor from the consumable. The cover comprises one or more dislodging elements adapted to dislodge the consumable such that, when the cover moves from the closed position to the open position: an attachment is weakened between the chamber and the consumable, and the consumable is partially ejected from the chamber without becoming attached to the cover.

An aerosol generation device comprises a chamber, a housing and a cover. The chamber is adapted to receive a consumable. The housing contains the chamber and comprises an opening through which the consumable can be removed from the chamber. The cover is configured to move between an open position where the opening of the housing is exposed and a closed position where the opening of the housing is closed. The aerosol generation device is adapted to generate an inhalable vapor from the consumable. The cover comprises one or more dislodging elements adapted to dislodge the consumable such that, when the cover moves from the closed position to the open position: an attachment is weakened between the chamber and the consumable, and the consumable is partially ejected from the chamber without becoming attached to the cover.

A heating assembly includes a main body and a high-frequency control assembly. The main body includes a heating chamber provided with a first opening. The main body further includes a heating element disposed in the heating chamber. The high-frequency control assembly is disposed outside the heating chamber. When in use, a tobacco material passes through the first opening and is disposed into the heating chamber; when the high-frequency control assembly is energized, an electromagnetic filed is produced, and the heating element produces heat to heat the tobacco material.

A heating assembly includes a main body and a high-frequency control assembly. The main body includes a heating chamber provided with a first opening. The main body further includes a heating element disposed in the heating chamber. The high-frequency control assembly is disposed outside the heating chamber. When in use, a tobacco material passes through the first opening and is disposed into the heating chamber; when the high-frequency control assembly is energized, an electromagnetic filed is produced, and the heating element produces heat to heat the tobacco material.

An aerosol-generating device includes a susceptor arranged to be inserted into an aerosol-generating substrate, a coil configured to heat the susceptor by induction heating, a magnetic force detector configured to detect a change in magnetic force of the susceptor according to a temperature change, and a controller configured to calculate a temperature of the susceptor based on the change of the magnetic force detected by the magnetic force detector. Accordingly, the aerosol-generating device accurately measures the temperature of the susceptor in a non-contact manner.

An aerosol-generating device includes a susceptor arranged to be inserted into an aerosol-generating substrate, a coil configured to heat the susceptor by induction heating, a magnetic force detector configured to detect a change in magnetic force of the susceptor according to a temperature change, and a controller configured to calculate a temperature of the susceptor based on the change of the magnetic force detected by the magnetic force detector. Accordingly, the aerosol-generating device accurately measures the temperature of the susceptor in a non-contact manner.