Patent Description:
Aerosol-generating systems for delivering an aerosol to a user typically comprise an aerosol-generating device and an aerosol-generating article. An aerosol-generating device may comprise an atomiser configured to generate an inhalable aerosol from an aerosol-forming substrate provided in the aerosol-generating article. Some known aerosol-generating devices comprise a heater such as an electric heater or an inductive heating device. The heater is configured to heat and vaporise the aerosol-forming substrate to generate an aerosol. Typical aerosol-forming substrates for use in aerosol-generating systems are nicotine formulations, which may be liquid nicotine formulations comprising an aerosol former such as glycerine and/or propylene glycol.

<CIT> discloses an aerosol-generating device comprising a heating chamber configured to receive an aerosol-generating article. The inner wall of the heating chamber comprises a coating. This coating may comprise a binder material and metal particles embedded in the binder material or a metal alloy. The coating is heat-reflective and dirt-repellent.

<CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT> and <CIT> describe glass compositions comprising silicon oxide, aluminium oxide, boron oxide, lithium oxide, magnesium oxide and one or more of calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide or titanium oxide.

It would be desirable to provide an aerosol-generating system in which a component or part of the heater is easy to clean.

There is disclosed a glass composition. The glass composition may comprise between about <NUM> percent by weight and about <NUM> weight percent by weight silicon oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide. The glass composition may comprise one or more of: calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide and titanium oxide.

There is also disclosed a glass composition comprising: between about <NUM> percent by weight and about <NUM> weight percent by weight silicon oxide; between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide; between about <NUM> percent by weight and about <NUM> percent by weight boron oxide; between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide; between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide; and one or more of: calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide and titanium oxide.

The present invention provides an aerosol-generating device comprising: a heater, wherein a component of the heater comprises a coating, wherein the coating is formed from the glass composition comprising: between <NUM> percent by weight and <NUM> weight percent by weight silicon oxide; between <NUM> percent by weight and <NUM> percent by weight aluminium oxide; between <NUM> percent by weight and <NUM> percent by weight boror oxide; between <NUM> percent by weight and <NUM> percent by weight lithium oxide; between <NUM> percent by weight and <NUM> percent by weight magnesium oxide; and one or more of: calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide and titanium oxide.

There is also provided an aerosol-generating system comprising an aerosol-generating device and an aerosol-generating article, as defined in independent claim <NUM>.

There is also disclosed an article. The article may be formed from a glass composition. The glass composition may comprise between about <NUM> percent by weight and about <NUM> weight percent by weight silicon oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide. The glass composition may comprise one or more of: calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide and titanium oxide.

There is also disclosed an article formed from a glass composition comprising: between about <NUM> percent by weight and about <NUM> weight percent by weight silicon oxide; between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide; between about <NUM> percent by weight and about <NUM> percent by weight boron oxide; between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide; between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide; and one or more of: calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide and titanium oxide.

Glass that is made using the glass composition may provide a smooth and hard surface that has no defects. In addition, the glass composition can be fired at a relatively low temperature compared to conventional glass compositions. This lower firing temperature allows the glass composition to be used in a wider variety of applications compared to conventional glass compositions. For example, the glass composition can be used as a coating to at least partially cover delicate components in a heater, such as a heater of an aerosol-generating device.

Using glass made from the glass composition as a coating for one or more components of a heater of an aerosol-generating device may provide for a smooth surface that can be easily cleaned by a user.

As used herein, the term "aerosol-generating article" refers to an article for producing an aerosol. An aerosol-generating article typically comprises an aerosol-forming substrate that is suitable and intended to be heated or combusted in order to release volatile compounds that can form an aerosol. A conventional cigarette is lit when a user applies a flame to one end of the cigarette and draws air through the other end. The localised heat provided by the flame and the oxygen in the air drawn through the cigarette causes the end of the cigarette to ignite, and the resulting combustion generates an inhalable smoke. In contrast, in "heated aerosol-generating articles", an aerosol is generated by heating an aerosol-forming substrate and not by combusting the aerosol-forming substrate. Known heated aerosol-generating articles include, for example, electrically heated aerosol-generating articles.

As used herein, the term "aerosol-forming substrate" refers to a substrate that is capable of producing upon heating volatile compounds, which can form an aerosol. The aerosol generated from aerosol-forming substrate may be visible to the human eye or invisible and may include vapours (for example, fine particles of substances, which are in a gaseous state, that are ordinarily liquid or solid at room temperature) as well as gases and liquid droplets of condensed vapours.

As used herein, the term "aerosol-generating device" refers to a device comprising a heater or a heating element that interacts with the aerosol-forming substrate of the aerosol-generating article to generate an aerosol.

As used herein, the term "coating" refers to an outer layer that at least partially covers the outer surface of the element the comprises the coating. In some examples, the coating may fully cover the outer surface of the element the comprises the coating.

The glass composition may comprise silicon oxide. For example, the glass composition may comprise silicon dioxide having the formula SiO<NUM>.

Including silicon oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including silicon oxide may improve the glass forming ability of the glass composition. Including silicon oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including silicon oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight silicon oxide. The glass composition may comprise at least about <NUM> percent by weight silicon oxide. The glass composition may comprise at least about <NUM> percent by weight silicon oxide. The glass composition may comprise at least about <NUM> percent by weight silicon oxide. The glass composition may comprise at least about <NUM> percent by weight silicon oxide. The glass composition may comprise at least about <NUM> percent by weight silicon oxide. The glass composition may comprise at least about <NUM> percent by weight silicon oxide. The glass composition may comprise at least about <NUM> percent by weight silicon oxide.

The glass composition may comprise less than about <NUM> percent by weight silicon oxide. The glass composition may comprise less than about <NUM> percent by weight silicon oxide. The glass composition may comprise less than about <NUM> percent by weight silicon oxide. The glass composition may comprise less than about <NUM> percent by weight silicon oxide. The glass composition may comprise less than about <NUM> percent by weight silicon oxide. The glass composition may comprise less than about <NUM> percent by weight silicon oxide. The glass composition may comprise less than about <NUM> percent by weight silicon oxide. The glass composition may comprise less than about <NUM> percent by weight silicon oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight silicon oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight silicon oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight silicon oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight silicon oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight.

The glass composition may comprise aluminium oxide. For example, the glass composition may comprise aluminium oxide having the formula Al<NUM>O<NUM>.

Including aluminium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including aluminium oxide may improve the glass forming ability of the glass composition. Including aluminium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including aluminium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight aluminium oxide. The glass composition may comprise at least about <NUM> percent by weight aluminium oxide. The glass composition may comprise at least about <NUM> percent by weight aluminium oxide. The glass composition may comprise at least about <NUM> percent by weight aluminium oxide. The glass composition may comprise at least about <NUM> percent by weight aluminium oxide. The glass composition may comprise at least about <NUM> percent by weight aluminium oxide. The glass composition may comprise at least about <NUM> percent by weight aluminium oxide.

The glass composition may comprise less than about <NUM> percent by weight aluminium oxide. The glass composition may comprise less than about <NUM> percent by weight aluminium oxide. The glass composition may comprise less than about <NUM> percent by weight aluminium oxide. The glass composition may comprise less than about <NUM> percent by weight aluminium oxide. The glass composition may comprise less than about <NUM> percent by weight aluminium oxide. The glass composition may comprise less than about <NUM> percent by weight aluminium oxide. The glass composition may comprise less than about <NUM> percent by weight aluminium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight aluminium oxide.

The glass composition may comprise boron oxide. For example, the glass composition may comprise boron trioxide having the formula B<NUM>O<NUM>.

Including boron oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including boron oxide may improve the glass forming ability of the glass composition. Including boron oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including boron oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight boron oxide. The glass composition may comprise at least about <NUM> percent by weight boron oxide. The glass composition may comprise at least about <NUM> percent by weight boron oxide. The glass composition may comprise at least about <NUM> percent by weight boron oxide. The glass composition may comprise at least about <NUM> percent by weight boron oxide. The glass composition may comprise at least about <NUM> percent by weight boron oxide. The glass composition may comprise at least about <NUM> percent by weight boron oxide. The glass composition may comprise at least about <NUM> percent by weight boron oxide.

The glass composition may comprise less than about <NUM> percent by weight boron oxide. The glass composition may comprise less than about <NUM> percent by weight boron oxide. The glass composition may comprise less than about <NUM> percent by weight boron oxide. The glass composition may comprise less than about <NUM> percent by weight boron oxide. The glass composition may comprise less than about <NUM> percent by weight boron oxide. The glass composition may comprise less than about <NUM> percent by weight boron oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight boron oxide.

The glass composition may comprise lithium oxide. For example, the glass composition may comprise lithium oxide having the formula Li<NUM>O.

Including lithium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including lithium oxide may improve the glass forming ability of the glass composition. Including lithium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including lithium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight lithium oxide. The glass composition may comprise at least about <NUM> percent by weight lithium oxide. The glass composition may comprise at least about <NUM> percent by weight lithium oxide. The glass composition may comprise at least about <NUM> percent by weight lithium oxide. The glass composition may comprise at least about <NUM> percent by weight lithium oxide. The glass composition may comprise at least about <NUM> percent by weight lithium oxide. The glass composition may comprise at least about <NUM> percent by weight lithium oxide.

The glass composition may comprise less than about <NUM> percent by weight lithium oxide. The glass composition may comprise less than about <NUM> percent by weight lithium oxide. The glass composition may comprise less than about <NUM> percent by weight lithium oxide. The glass composition may comprise less than about <NUM> percent by weight lithium oxide. The glass composition may comprise less than about <NUM> percent by weight lithium oxide. The glass composition may comprise less than about <NUM> percent by weight lithium oxide. The glass composition may comprise less than about <NUM> percent by weight lithium oxide. The glass composition may comprise less than about <NUM> percent by weight lithium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight lithium oxide.

The glass composition may comprise magnesium oxide. For example, the glass composition may comprise magnesium oxide having the formula MgO.

Including magnesium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including magnesium oxide may improve the glass forming ability of the glass composition. Including magnesium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including magnesium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight magnesium oxide. The glass composition may comprise at least about <NUM> percent by weight magnesium oxide. The glass composition may comprise at least about <NUM> percent by weight magnesium oxide. The glass composition may comprise at least about <NUM> percent by weight magnesium oxide. The glass composition may comprise at least about <NUM> percent by weight magnesium oxide. The glass composition may comprise at least about <NUM> percent by weight magnesium oxide.

The glass composition may comprise less than about <NUM> percent by weight magnesium oxide. The glass composition may comprise less than about <NUM> percent by weight magnesium oxide. The glass composition may comprise less than about <NUM> percent by weight magnesium oxide. The glass composition may comprise less than about <NUM> percent by weight magnesium oxide. The glass composition may comprise less than about <NUM> percent by weight magnesium oxide. The glass composition may comprise less than about <NUM> percent by weight magnesium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight magnesium oxide.

The glass composition may comprise calcium oxide. For example the glass composition may comprise calcium oxide having the formula of CaO.

Including calcium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including calcium oxide may improve the glass forming ability of the glass composition. Including calcium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including calcium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight calcium oxide. The glass composition may comprise at least about <NUM> percent by weight calcium oxide. The glass composition may comprise at least about <NUM> percent by weight calcium oxide. The glass composition may comprise at least about <NUM> percent by weight calcium oxide. The glass composition may comprise at least about <NUM> percent by weight calcium oxide. The glass composition may comprise at least about <NUM> percent by weight calcium oxide. The glass composition may comprise at least about <NUM> percent by weight calcium oxide.

The glass composition may comprise less than about <NUM> percent by weight calcium oxide. The glass composition may comprise less than about <NUM> percent by weight calcium oxide. The glass composition may comprise less than about <NUM> percent by weight calcium oxide. The glass composition may comprise less than about <NUM> percent by weight calcium oxide. The glass composition may comprise less than about <NUM> percent by weight calcium oxide. The glass composition may comprise less than about <NUM> percent by weight calcium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight calcium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight calcium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight calcium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight calcium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight calcium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight calcium oxide.

The glass composition may comprise gallium oxide. For example, the glass composition may comprise gallium (III) trioxide having the formula G<NUM>O<NUM>.

Including gallium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including gallium oxide may improve the glass forming ability of the glass composition. Including gallium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including gallium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight gallium oxide. The glass composition may comprise at least about <NUM> percent by weight gallium oxide. The glass composition may comprise at least about <NUM> percent by weight gallium oxide. The glass composition may comprise at least about <NUM> percent by weight gallium oxide. The glass composition may comprise at least about <NUM> percent by weight gallium oxide. The glass composition may comprise at least about <NUM> percent by weight gallium oxide. The glass composition may comprise at least about <NUM> percent by weight gallium oxide. The glass composition may comprise at least about <NUM> percent by weight gallium oxide.

The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide. The glass composition may comprise less than about <NUM> percent by weight gallium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight gallium oxide.

The glass composition may comprise potassium oxide. For example, the glass composition may comprise potassium oxide having the formula K<NUM>O.

Including potassium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including potassium oxide may improve the glass forming ability of the glass composition. Including potassium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including potassium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide. The glass composition may comprise at least about <NUM> percent by weight potassium oxide.

The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide. The glass composition may comprise less than about <NUM> percent by weight potassium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight potassium oxide.

The glass composition may comprise samarium oxide. For example, the glass composition may comprise samarium (III) oxide having the formula Sm<NUM>O<NUM>.

Including samarium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including samarium oxide may improve the glass forming ability of the glass composition. Including samarium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including samarium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide. The glass composition may comprise at least about <NUM> percent by weight samarium oxide.

The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide. The glass composition may comprise less than about <NUM> percent by weight samarium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight samarium oxide.

The glass composition may comprise strontium oxide. For example, the glass composition may comprise strontium oxide having the formula SrO.

Including strontium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including strontium oxide may improve the glass forming ability of the glass composition. Including strontium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including strontium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide. The glass composition may comprise at least about <NUM> percent by weight strontium oxide.

The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide. The glass composition may comprise less than about <NUM> percent by weight strontium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight strontium oxide.

The glass composition may comprise titanium oxide. For example, the glass composition may comprise titanium (IV) oxide having the formula TiO<NUM>.

Including titanium oxide in the glass composition may lead to the low temperature formation of a eutectic composition. Including titanium oxide may improve the glass forming ability of the glass composition. Including titanium oxide in the composition may provide an increase in the coefficient of linear thermal expansion. Including titanium oxide in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide. The glass composition may comprise at least about <NUM> percent by weight titanium oxide.

The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide. The glass composition may comprise less than about <NUM> percent by weight titanium oxide.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight titanium oxide.

The glass composition may comprise fluorine.

Including fluorine in the glass composition may lead to the low temperature formation of a eutectic composition. Including fluorine may improve the glass forming ability of the glass composition. Including fluorine in the composition may provide an increase in the coefficient of linear thermal expansion. Including fluorine in the composition may improve compatibility with a ceramic substrate.

The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine.

The glass composition may comprise less than about <NUM> percent by weight fluorine. The glass composition may comprise less than about <NUM> percent by weight fluorine. The glass composition may comprise less than about <NUM> percent by weight fluorine. The glass composition may comprise less than about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine. The glass composition may comprise at least about <NUM> percent by weight fluorine.

The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine. The glass composition may comprise between about <NUM> percent by weight and about <NUM> percent by weight fluorine.

The component of the heater may be a heating element.

The heating element may be a heating blade.

In some examples, the whole of the heater may comprise a coating formed from the glass composition according to the invention.

The coating may be a protective coating.

The article may be a heater. The heater may be a heater for an aerosol-generating device.

The article may be a component of a heater.

The article may be a heating element. The heating element may be a heating blade.

It will be appreciated that any features described herein in relation to one embodiment may also be applicable to other embodiments. A feature described in relation to one embodiment may be equally applicable to another embodiment in accordance with this disclosure.

<FIG> illustrates schematically an example of an aerosol-generating device including a heater, wherein a component of the heater has a coating formed from a glass composition as described herein; and.

<FIG> illustrates schematically a cross-section view of the component of the heater shown in <FIG>.

During use of an aerosol-generating device, waste residue can build up on a surface of the atomiser. Therefore, atomisers, particularly heaters, should be cleaned regularly to keep them in good working order. However, if a component of an atomiser has a rough surface then the surface of that component becomes difficult to clean effectively and waste residue can be left behind after the component has been cleaned. Over time, this waste residue builds up on the atomiser surface, which leads to the performance of the atomiser deteriorating.

Aerosol-generating devices that have a heater may be particularly susceptible to the problem of waste residue building up on a surface of the heater. Aerosol-generating devices having a heating blade type heater may be more likely to experience a build-up of waste residue on their surface compared to other types of heaters.

The present inventors realised that the outer surface of one or more components of the heater can be coated in a glass composition in order to provide a smoother surface. For example, glass compositions are used for similar reasons in dental applications. However, such glass compositions need to be fired at a temperature above <NUM>. Firing a component of a heater at such a high temperature can cause partial melting of parts of the heater, such as the gold and silver containing heating tracks. This partial melting may generate defects such as small bubbles on the surface of a glass coating, which may impact the smoothness of the coating and thus make the heater more difficult to clean.

It would therefore be desirable to provide a glass composition that can be used to provide a smooth outer coating, and that can also be fired at a relatively low temperature compared to conventional glass compositions.

The example of <FIG> shows a portion of an aerosol-generating device <NUM>.

The aerosol-generating device <NUM> includes a heater <NUM>. The heater <NUM> is for heating an aerosol-generating substrate contained within an aerosol-generating article. In the example of <FIG> the heater <NUM> includes a heating blade <NUM>. In other examples, the heater <NUM> may include an alternative heater arrangement.

In the example of <FIG>, the heater <NUM> is mounted within a receiving chamber.

The aerosol-generating device <NUM> defines a plurality of air holes <NUM> for allowing air to flow into an aerosol-generating article engaged with the aerosol-generating device <NUM> and received within the receiving chamber.

The aerosol-generating device <NUM> has a power supply. In the example of <FIG>, the power supply is a battery <NUM>.

The aerosol-generating device <NUM> includes control electronics <NUM> for controlling operation of the aerosol-generating device <NUM>. The control electronics <NUM> may include a processor or the like.

The example of the aerosol-generating device <NUM> illustrated in <FIG> is designed to be engaged by an aerosol-generating article in order for an aerosol-forming substrate contained within the aerosol-generating article to be consumed.

In use, once an aerosol-generating article is engaged with the aerosol-generating device <NUM>, a user activates the heater <NUM>. The heater <NUM> heats the aerosol-forming substrate to a temperature of about <NUM> degrees Celsius. At this temperature, volatile compounds are evolved from the aerosol-forming substrate. These compounds condense to form an aerosol. The user then draws on a mouth-end of the aerosol-generating article and the aerosol is drawn through a filter provided in the aerosol-generating article and into the user's mouth.

The example of <FIG> shows a cross-section view of the heating blade <NUM> of <FIG>.

The heating blade <NUM> has a coating <NUM> on at least part of its external surface. In some examples, the heating blade <NUM> has a coating <NUM> on all of its external surface.

The heating blade <NUM> also includes one or more electrical tracks <NUM>.

The coating <NUM> is formed from a glass composition. According to the invention, the glass composition includes between <NUM> percent by weight and <NUM> weight percent by weight silicon oxide; between <NUM> percent by weight and <NUM> percent by weight aluminium oxide; between <NUM> percent by weight and <NUM> percent by weight boror oxide; between <NUM> percent by weight and <NUM> percent by weight lithium oxide; between <NUM> percent by weight and <NUM> percent by weight magnesium oxide; and one or more of: calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide and titanium oxide. In some examples, the glass composition also include fluorine.

Example compositions of the glass composition according to the invention (Examples A, B, C, D and E) are prepared having the compositions shown in Table <NUM>.

The compositions of Examples A, B, C, D and E form deep multicomponent eutectics, which combine fusibility with high hardness.

A coating <NUM> having a glass composition of Examples A, B, C, D and E is prepared and applied to a heating blade <NUM> by:.

In some examples, instead of being spray coated, the fluid may be screen printed on to the heating blade <NUM>.

Accordingly, glasses having the compositions of Examples A, B, C, D and E are formed at temperatures that are around <NUM> below the firing temperature of conventional glass.

Glasses formed from the glass compositions of Examples A, B, C, D and E are able to be used as smooth coatings with a Vickers micro hardness of between <NUM> and <NUM>/mm<NUM>.

The starting materials for the glass compositions of Examples A, B, C, D and E include the following materials shown in Table <NUM>.

Table <NUM> shows the roughness of the Example glass compositions A, B, C, D and E.

A baseline roughness (Ra) of industrial glass is <NUM>.

Accordingly, the data of Table <NUM> shows that the glass compositions of all of the Examples A, B, C, D and E form glasses having a roughness that is much lower than industrial glass. Indeed, the glasses formed from the glass compositions of Examples B and C have the smoothest surfaces of the Examples.

Glass that is made using the glass compositions of the Examples A, B, C, D and E may therefore provide a smooth, hard surface that is defect-free and can be formed at a relatively low firing temperature. Thus, when the glass is used as a coating on a component of a heater of an aerosol-generating device, the resulting smooth surface allows for the component to be easier to clean. The relatively low firing temperature, which is about <NUM> below typical firing temperatures, means that delicate electrical tracks within the heater are not damaged during the firing process. This also improves the resulting smoothness of the outer surface of the component. By making a component of the heater easier to clean, deterioration of the heater is reduced, which improves the overall performance of the aerosol-generating device.

Claim 1:
An aerosol-generating device (<NUM>) comprising:
A heater (<NUM>),
wherein a component (<NUM>) of the heater (<NUM>) comprises a coating (<NUM>),
wherein the coating (<NUM>) is formed from a glass composition comprising:
between <NUM> percent by weight and <NUM> weight percent by weight silicon oxide;
between <NUM> percent by weight and <NUM> percent by weight aluminium oxide;
between <NUM> percent by weight and <NUM> percent by weight boron oxide;
between <NUM> percent by weight and <NUM> percent by weight lithium oxide;
between <NUM> percent by weight and <NUM> percent by weight magnesium oxide; and
one or more of: calcium oxide, gallium oxide, potassium oxide, samarium oxide, strontium oxide and titanium oxide.