Example embodiments relate to a method of protecting a surface of an e-vaping device portion from corrosion, the method including preparing a coating mixture configured to protect the surface from corrosion, and coating the surface with a protective coating based on the coating mixture, wherein the coating is performed via one of electrodeposition, dipping, spraying, and vapor deposition, and the coating mixture includes at least one of a silane and a resin.

Example embodiments relate to a method of protecting a surface of an e-vaping device portion from corrosion, the method including preparing a coating mixture configured to protect the surface from corrosion, and coating the surface with a protective coating based on the coating mixture, wherein the coating is performed via one of electrodeposition, dipping, spraying, and vapor deposition, and the coating mixture includes at least one of a silane and a resin.

An electronic cigarette is described which comprises an outer housing sleeve having an open end and a closed end and a functional insert comprising electrical components, wherein the functional insert is arranged to be introduced through the open end of the outer housing sleeve and is held within the outer housing sleeve. By grouping the functional electronic components together on the functional insert and by providing the device housing in the form of a sleeve, the assembly process is simplified as the functional components can be assembled in a first assembly step and then subsequently sleeved within the outer housing in a single step, thus reducing the complexity of the assembly procedure.

An electronic cigarette is described which comprises an outer housing sleeve having an open end and a closed end and a functional insert comprising electrical components, wherein the functional insert is arranged to be introduced through the open end of the outer housing sleeve and is held within the outer housing sleeve. By grouping the functional electronic components together on the functional insert and by providing the device housing in the form of a sleeve, the assembly process is simplified as the functional components can be assembled in a first assembly step and then subsequently sleeved within the outer housing in a single step, thus reducing the complexity of the assembly procedure.

An article for use within a non-combustible aerosol provision system includes an aerosol-generating material having a top side, a barrier positioned adjacent to the top side of the aerosol-generating material and at least one passageway defined by the barrier and extending away from the top side of the aerosol-generating material. The at least one passageway is configured to, in use, allow aerosol to escape from the aerosol-generating material and provide a condensation region for the escaping aerosol.

An article for use within a non-combustible aerosol provision system includes an aerosol-generating material having a top side, a barrier positioned adjacent to the top side of the aerosol-generating material and at least one passageway defined by the barrier and extending away from the top side of the aerosol-generating material. The at least one passageway is configured to, in use, allow aerosol to escape from the aerosol-generating material and provide a condensation region for the escaping aerosol.

A vaporization element of an electronic vaporization device includes: a porous substrate; and a heating layer. The porous substrate includes a vaporization surface and the heating layer covers the vaporization surface. The heating layer includes a conductive layer and a stabilizing layer, the conductive layer covers the vaporization surface, and the stabilizing layer covers a surface of the conductive layer far from the porous substrate. A resistivity of the stabilizing layer is higher than a resistivity of the conductive layer. An oxidation resistance of the stabilizing layer is lower than an oxidation resistance of the conductive layer.

A vaporization element of an electronic vaporization device includes: a porous substrate; and a heating layer. The porous substrate includes a vaporization surface and the heating layer covers the vaporization surface. The heating layer includes a conductive layer and a stabilizing layer, the conductive layer covers the vaporization surface, and the stabilizing layer covers a surface of the conductive layer far from the porous substrate. A resistivity of the stabilizing layer is higher than a resistivity of the conductive layer. An oxidation resistance of the stabilizing layer is lower than an oxidation resistance of the conductive layer.

The present disclosure provides an atomization device manufacturing method and an atomization device. The method steps are, firstly obtaining a hollow rod, two ends of which are respectively provided with an opening, secondly assembling an atomization component to the opening at one end of the rod, then assembling a battery component in the rod and electrically connecting the battery component with the atomization component, and finally assembling a sensing component to the opening at the other end of the rod and electrically connecting the sensing component with the battery component.

The present disclosure provides an atomization device manufacturing method and an atomization device. The method steps are, firstly obtaining a hollow rod, two ends of which are respectively provided with an opening, secondly assembling an atomization component to the opening at one end of the rod, then assembling a battery component in the rod and electrically connecting the battery component with the atomization component, and finally assembling a sensing component to the opening at the other end of the rod and electrically connecting the sensing component with the battery component.