An aerosol generating device comprises a magnetic field generator and a heater for heating a smokable material; the heater comprises a susceptor portion and an infrared emission portion, the susceptor portion is penetrated by a magnetic field to generate heat and heat the smokable material by heat conduction, and the infrared emission portion receives the heat of the susceptor portion, and is excited by heating to radiate infrared rays to heat the smokable material. During the use of the above aerosol generating device, on the one hand, the susceptor portion generates heat by inductive heating so that the smokable material is directly heated by heat conduction; and on the other hand, the infrared emission portion is excited by the heat of the susceptor portion to radiate infrared rays, thereby assisting in the heating of the smokable material, and improving the utilization efficiency of heat.

A smoking set comprises: a heating cavity and a heater; a first detection module, being configured to detect whether an object exists at a first position in the heating cavity to output a first detection signal; a second detection module, being configured to detect whether an object exists at a second position in the heating cavity to output a second detection signal; a microcontroller, being configured to: acquire the first detection signal and the second detection signal; identify object situation in the heating cavity according to different combinations of the first detection signal and the second detection signal. According to the present application, object situation in the heating cavity is identified according to different combinations of the first detection signal and the second detection signal; and the heater may be controlled to start heating or be turned off according to the identification result.

A smoking set comprises: a heating cavity and a heater; a first detection module, being configured to detect whether an object exists at a first position in the heating cavity to output a first detection signal; a second detection module, being configured to detect whether an object exists at a second position in the heating cavity to output a second detection signal; a microcontroller, being configured to: acquire the first detection signal and the second detection signal; identify object situation in the heating cavity according to different combinations of the first detection signal and the second detection signal. According to the present application, object situation in the heating cavity is identified according to different combinations of the first detection signal and the second detection signal; and the heater may be controlled to start heating or be turned off according to the identification result.

The present disclosure provides an atomizing device and an assembling method thereof. The atomizing device includes a first body and a second body. The first body includes a first outer case and an atomizing component. The atomizing component is disposed in the first outer case. The second body is detachably connected to the first body, wherein the second body includes a second outer case, a controlling component, and a battery component. The controlling component is disposed on one side of the second outer case close to the atomizing component, wherein the controlling component is electrically connected to the atomizing component. The battery component is disposed on one side of the second outer case away from the atomizing component, wherein the battery component is electrically connected to the controlling component.

The present disclosure provides an atomizing device and an assembling method thereof. The atomizing device includes a first body and a second body. The first body includes a first outer case and an atomizing component. The atomizing component is disposed in the first outer case. The second body is detachably connected to the first body, wherein the second body includes a second outer case, a controlling component, and a battery component. The controlling component is disposed on one side of the second outer case close to the atomizing component, wherein the controlling component is electrically connected to the atomizing component. The battery component is disposed on one side of the second outer case away from the atomizing component, wherein the battery component is electrically connected to the controlling component.

An aerosol-generating device is disclosed. The aerosol-generating device includes a first container accommodating an aerosol-generating substance, a heater heating the aerosol-generating substance, a second container configured to be rotatable and including chambers, a rotation detection sensor sensing rotation of the second container, and a controller. The controller determines any one of the chambers to be an application chamber through which an aerosol passes based on a signal received from the rotation detection sensor, and determines usage of a chamber determined to be the application chamber. The heater is heated to a first temperature or higher when the usage is equal to or greater than a first reference and less than a second reference, and is heated to a second temperature or higher when the usage is equal to or greater than the second reference and less than a third reference. The second temperature is higher than the first temperature.

An aerosol-generating device is disclosed. The aerosol-generating device includes a first container accommodating an aerosol-generating substance, a heater heating the aerosol-generating substance, a second container configured to be rotatable and including chambers, a rotation detection sensor sensing rotation of the second container, and a controller. The controller determines any one of the chambers to be an application chamber through which an aerosol passes based on a signal received from the rotation detection sensor, and determines usage of a chamber determined to be the application chamber. The heater is heated to a first temperature or higher when the usage is equal to or greater than a first reference and less than a second reference, and is heated to a second temperature or higher when the usage is equal to or greater than the second reference and less than a third reference. The second temperature is higher than the first temperature.

The present disclosure provides an atomizing device including an atomizing component, a controlling component, and a battery component. The atomizing component includes an atomizing piece, an accommodating piece, a piston, and an induction coil. The accommodating piece is disposed on the atomizing piece. Wherein, the accommodating piece is in fluid communication with the atomizing piece, and the accommodating piece is configured to store a filler. The piston is disposed in the accommodating piece and has a magnet inside. The induction coil surrounds the accommodating piece, and the induction coil is configured to drive the piston to move toward the atomizing piece. The controlling component is disposed on one side of the atomizing component is electrically connected to the atomizing component. The battery component is disposed on one side of the controlling component away from the atomizing component and is electrically connected to the controlling component.

The present disclosure provides an atomizing device including an atomizing component, a controlling component, and a battery component. The atomizing component includes an atomizing piece, an accommodating piece, a piston, and an induction coil. The accommodating piece is disposed on the atomizing piece. Wherein, the accommodating piece is in fluid communication with the atomizing piece, and the accommodating piece is configured to store a filler. The piston is disposed in the accommodating piece and has a magnet inside. The induction coil surrounds the accommodating piece, and the induction coil is configured to drive the piston to move toward the atomizing piece. The controlling component is disposed on one side of the atomizing component is electrically connected to the atomizing component. The battery component is disposed on one side of the controlling component away from the atomizing component and is electrically connected to the controlling component.

A control device for controlling operation of a vaping apparatus. The control device comprises control circuitry to control activation of the vaping source, measurement circuitry to obtain a temperature-dependent parameter of the vaping source, and memory circuitry for data storage. The control device is configured to determine the ambient temperature, to obtain the parameter at the ambient temperature as an initial parameter, to set and store a target parameter for stopping activation of the vaping source, and to stop activation of the vaping source when the target parameter has been reached.