An aerosol generating device includes a planar heating element including a mesh of electrically conductive fibres, a heating rod in contact with a central portion of the planar heating element to provide a central region of high current density, thereby providing a temperature gradient across the planar heating element during use, a liquid store, and a liquid transport element arranged between the liquid store and the planar heating element and configured to transport liquid from the liquid store to the planar heating element under capillary action during use, wherein the liquid transport element is arranged in contact with an edge portion of the mesh.

An atomizer of an electronic atomizing inhaler, includes a casing body, provided with a cap at the opening of the front end, with a gas-outlet aperture on the cap, and provided with a rear closure at the opening of the rear end, with a gas-inlet aperture on the rear closure; a liquid-container and a heater provided in the cavity formed by the casing body, the cap and the rear closure, an airflow-passage being provided between the casing body and the liquid-container; a liquid-guiding device closing the mouth part of the liquid-container, with no liquid-storage medium provided in the liquid-container; and a heater provided on the top of the rear closure, contacting the lower surface of the liquid-guiding device. An electronic atomizing inhaler is also provided.

An atomizer of an electronic atomizing inhaler, includes a casing body, provided with a cap at the opening of the front end, with a gas-outlet aperture on the cap, and provided with a rear closure at the opening of the rear end, with a gas-inlet aperture on the rear closure; a liquid-container and a heater provided in the cavity formed by the casing body, the cap and the rear closure, an airflow-passage being provided between the casing body and the liquid-container; a liquid-guiding device closing the mouth part of the liquid-container, with no liquid-storage medium provided in the liquid-container; and a heater provided on the top of the rear closure, contacting the lower surface of the liquid-guiding device. An electronic atomizing inhaler is also provided.

The present invention discloses an atomizer. The atomizer includes a concentrate reservoir volume that is in fluid communication with a concentrate vaporization assembly. The concentrate vaporization assembly includes a frit adapted to absorb concentrate from the concentrate reservoir volume. The concentrate vaporization assembly further includes a heating element adapted to heat the frit and absorbed concentrate. The atomizer further includes a vapor collection and discharge assembly including a vapor accumulation chamber in fluid communication with the frit and a vapor evacuation channel in fluid communication with the vapor accumulation chamber and in fluid communication with an egress port. The heating element is activated by a user control of a switch on a battery, which causes the concentrate contained within the frit filter to vaporize, and the user inhales resulting vapor by inhaling at the egress port of the vapor evacuation channel.

The present invention discloses an atomizer. The atomizer includes a concentrate reservoir volume that is in fluid communication with a concentrate vaporization assembly. The concentrate vaporization assembly includes a frit adapted to absorb concentrate from the concentrate reservoir volume. The concentrate vaporization assembly further includes a heating element adapted to heat the frit and absorbed concentrate. The atomizer further includes a vapor collection and discharge assembly including a vapor accumulation chamber in fluid communication with the frit and a vapor evacuation channel in fluid communication with the vapor accumulation chamber and in fluid communication with an egress port. The heating element is activated by a user control of a switch on a battery, which causes the concentrate contained within the frit filter to vaporize, and the user inhales resulting vapor by inhaling at the egress port of the vapor evacuation channel.

An e-cigarette includes a housing having a liquid section for holding a liquid and a battery section for holding a battery, which liquid section and battery section are configured to be coupled to each other, and a wick to take up the liquid, a heating member for heating the wick, wherein the liquid section includes a liquid reservoir provided with a liquid outlet to supply liquid to the wick and an air duct to create an air flow along the wick and to an air outlet.

An e-cigarette includes a housing having a liquid section for holding a liquid and a battery section for holding a battery, which liquid section and battery section are configured to be coupled to each other, and a wick to take up the liquid, a heating member for heating the wick, wherein the liquid section includes a liquid reservoir provided with a liquid outlet to supply liquid to the wick and an air duct to create an air flow along the wick and to an air outlet.

A liquid-conveying susceptor assembly is provided for conveying and inductively heating an aerosol-forming liquid under an influence of an alternating magnetic field, the assembly including: an array of inductively heatable longitudinal filaments arranged side by side; and an array of transverse filaments arranged side by side and crossing the longitudinal filaments transverse to a length extension of the longitudinal filaments, in which the transverse filaments only extend along a length portion of the longitudinal filaments such that the assembly further includes at least one grid portion and at least one non-grid portion, in which in the grid portion the transverse filaments and the longitudinal filaments cross each other, in which in the non-grid portion the assembly only includes the longitudinal filaments, but no transverse filaments, and in which length dimension of the non-grid portion is at least 20 percent of a length dimension of the longitudinal filaments.

A liquid-conveying susceptor assembly is provided for conveying and inductively heating an aerosol-forming liquid under an influence of an alternating magnetic field, the assembly including: an array of inductively heatable longitudinal filaments arranged side by side; and an array of transverse filaments arranged side by side and crossing the longitudinal filaments transverse to a length extension of the longitudinal filaments, in which the transverse filaments only extend along a length portion of the longitudinal filaments such that the assembly further includes at least one grid portion and at least one non-grid portion, in which in the grid portion the transverse filaments and the longitudinal filaments cross each other, in which in the non-grid portion the assembly only includes the longitudinal filaments, but no transverse filaments, and in which length dimension of the non-grid portion is at least 20 percent of a length dimension of the longitudinal filaments.

An evaporator for an aerosol generating device is described. The evaporator comprises a heating body (101) comprising a plurality of channels (102) arranged through the heating body between an inlet surface (103) and an outlet surface (104). The channels are configured to transport liquid from the inlet surface through the heating body by capillary action. The heating body comprises electrically conductive material (120) and the evaporator further comprises circuitry (116) for providing a current through the electrically conductive material to provide resistive heating of the heating body to evaporate a liquid passing through the channels. The heating body and circuitry are configured to provide a positive temperature gradient across the heating body from the inlet surface to the outlet surface.