An aerosol provision system is disclosed comprising an aerosol generating component for generating an aerosol from an aerosol generating material. The system further comprises a consumable comprising aerosol generating material, the consumable defining a surface at which at least part of the aerosol generating material is disposed the surface having a characteristic extent in a first direction and a characteristic extent in a second direction and a movement mechanism for providing relative movement between the aerosol generating component and the consumable. The movement mechanism is arranged to provide relative movement between the aerosol generating component and the consumable along an axis substantially parallel to the first direction and along an axis substantially parallel to the second direction.

An aerosol provision system is disclosed comprising an aerosol generating component for generating an aerosol from an aerosol generating material. The system further comprises a consumable comprising aerosol generating material, the consumable defining a surface at which at least part of the aerosol generating material is disposed the surface having a characteristic extent in a first direction and a characteristic extent in a second direction and a movement mechanism for providing relative movement between the aerosol generating component and the consumable. The movement mechanism is arranged to provide relative movement between the aerosol generating component and the consumable along an axis substantially parallel to the first direction and along an axis substantially parallel to the second direction.

A method of generating aerosol from a consumable is disclosed. The consumable comprises a corrugated surface having troughs extending along the consumable in an axial direction, the troughs being provided with aerosol generating material. The method comprising sequentially supplying heat to selected one or more troughs, such that at a given time, heat is directly applied to the selected one or more troughs by a heating element.

A method of generating aerosol from a consumable is disclosed. The consumable comprises a corrugated surface having troughs extending along the consumable in an axial direction, the troughs being provided with aerosol generating material. The method comprising sequentially supplying heat to selected one or more troughs, such that at a given time, heat is directly applied to the selected one or more troughs by a heating element.

Cartridges for vaporizer devices are provided. In one exemplary embodiment, the cartridge can include first and second storage chambers each configured to hold a respective fraction of a vaporizable material, a vaporization chamber that includes an elongate member that is in fluid communication with the first and second storage chambers and configured to receive the vaporizable material, a magnetic element disposed within a channel of the elongate member, and a conductive element that is configured to generate a first motive force to drive the magnetic element between first and second positions and further configured to substantially vaporize the vaporizable material within the elongate member. Vaporizer devices are also provided.

An atomization assembly comprises an e-liquid reservoir, a porous body, and a healing element. The e-liquid reservoir comprises an e-liquid storage cavity (b) for storing e-liquid. Used for adsorbing e-liquid in the e-liquid storage cavity, the porous body comprises an e-liquid contract surface, an e-liquid atomization surface and an air inlet surface and it adsorbs the e-liquid in the e-liquid storage cavity by means of the e-liquid contact surface; the air inlet surface is for allowing gas to flow into the porous body and flow into the e-liquid storage cavity by means of the porous body; the distance between the air inlet surface and the e-liquid contact surface is smaller than the distance between the e-liquid atomization surface and the e-liquid contact surface, and at least part of the heating element is in contact with the e-liquid atomization surface so as to atomize the e-liquid on the e-liquid atomization surface.

An atomization assembly comprises an e-liquid reservoir, a porous body, and a healing element. The e-liquid reservoir comprises an e-liquid storage cavity (b) for storing e-liquid. Used for adsorbing e-liquid in the e-liquid storage cavity, the porous body comprises an e-liquid contract surface, an e-liquid atomization surface and an air inlet surface and it adsorbs the e-liquid in the e-liquid storage cavity by means of the e-liquid contact surface; the air inlet surface is for allowing gas to flow into the porous body and flow into the e-liquid storage cavity by means of the porous body; the distance between the air inlet surface and the e-liquid contact surface is smaller than the distance between the e-liquid atomization surface and the e-liquid contact surface, and at least part of the heating element is in contact with the e-liquid atomization surface so as to atomize the e-liquid on the e-liquid atomization surface.

Provided are an atomization assembly and an electronic cigarette. The electronic cigarette comprises: the atomisation assembly, and a battery assembly. The atomization assembly comprises an atomization component and first electrodes, each first electrode comprises a base portion and a connecting portion, the connecting portion extends along a first direction of the electronic cigarette, and the base portion extends along a second direction basically perpendicular to the first direction. The battery assembly comprises second electrodes, each second electrode abuts against the bass portion, and the second electrode extends in the first direction of the electronic cigarette and is deviated from the connecting portion. Good contact between foe first electrodes of the atomization assembly anti the second electrodes of the battery assembly can be ensured in addition, the first electrodes are connected and fixed by means of the connecting portions so that the overall structure is stable, and electrical connection is reliable.

Provided are an atomization assembly and an electronic cigarette. The electronic cigarette comprises: the atomisation assembly, and a battery assembly. The atomization assembly comprises an atomization component and first electrodes, each first electrode comprises a base portion and a connecting portion, the connecting portion extends along a first direction of the electronic cigarette, and the base portion extends along a second direction basically perpendicular to the first direction. The battery assembly comprises second electrodes, each second electrode abuts against the bass portion, and the second electrode extends in the first direction of the electronic cigarette and is deviated from the connecting portion. Good contact between foe first electrodes of the atomization assembly anti the second electrodes of the battery assembly can be ensured in addition, the first electrodes are connected and fixed by means of the connecting portions so that the overall structure is stable, and electrical connection is reliable.

A dual-airway intake structure used for an aerosol generating device includes a base and a sensor. The base is provided with a sensing cavity: the sensing cavity is in communication with an air outlet passage of the aerosol generating device; a mounting portion is provided in the sensing cavity; the mounting portion is provided with a mounting cavity; the sensor is mounted on the mounting portion and seals the mounting cavity: the base is provided with air inlets and a communicating hole; the air inlets are in communication with the sensing cavity and the outside atmosphere; the communicating hole is in communication with the mounting cavity and the outside atmosphere; the mounting portion is provided with a communicating groove; the communicating groove is in communication with the mounting cavity and the sensing cavity.