Cartridge of a stick-shaped aerosol generating article for use with induction heating aerosol generators.

Abstract

The present invention relates to a cartridge of stick-shaped aerosol generating articles for use with an inductively heated aerosol generating device. The cartridge includes a vaporization chamber (111) at a distal end portion of the cartridge for vaporizing an aerosol-forming liquid therein, and a reservoir chamber (112) proximal to the vaporization chamber for storing the aerosol-forming liquid. The cartridge further includes a liquid-transport susceptor arrangement (140) configured and arranged to be inductively heated when used with the device to transport the aerosol-forming liquid from the reservoir chamber into the vaporization chamber and vaporize the aerosol-forming liquid in the vaporization chamber. The cartridge further includes a vapor transport conduit (120) providing fluid communication for the vaporized aerosol-forming liquid from the vaporization chamber to a proximal region of the reservoir chamber. In addition, the cartridge includes a proximal end cap (130) forming at least a proximal end wall member of the reservoir chamber, the proximal end cap including a through-hole (135) through which the proximal end portion of the vapor transport conduit passes or is supported or integrally terminates in. The proximal end cap includes a distal recess (136) forming a distal portion of the throughbore in which the proximal end portion of the vapor carrying conduit is supported. The inner cross section of the distal recess is greater than the inner cross section of the proximal portion of the throughbore other than the distal portion. The invention further relates to an aerosol-generating article comprising such a cartridge.

Description

【Technical Field】 【0001】 The present disclosure relates to a cartridge for a stick-shaped aerosol-generating article configured for use in an inductive heating aerosol-generating device. The present disclosure further relates to such articles, as well as to an aerosol-generating system comprising such aerosol-generating articles and such aerosol-generating devices. 【Background Art】 【0002】 Systems for generating inhalable aerosols by inductively heating an aerosol-forming substrate having the ability to release a volatile compound upon heating are generally known from the prior art. To heat the substrate, the substrate is disposed in thermal proximity to, or in physical direct contact with, a susceptor that is inductively heatable under the influence of an alternating electromagnetic field, or can be in thermal proximity or in physical direct contact. The susceptor and the substrate may be assembled together with an aerosol-forming article configured to be received within a corresponding cavity of the aerosol-generating device. The device comprises an induction source for generating an alternating magnetic field within the cavity in order to inductively heat the susceptor, and hence the substrate, when the article is received within the cavity. The article may further comprise a mouthpiece through which the user can inhale in order to create an airflow through the article from the substrate towards the mouthpiece. Thus, when the user smokes during operation of the device, the volatile compounds released from the heated substrate are entrained by the airflow, cooled and condensed to form an aerosol exiting the article at the mouthpiece. The aerosol-generating article and the aerosol-generating device together form an aerosol-generating system, with the article generally being a disposable consumable and the device generally being reusable with other components. 【Summary of the Invention】 【Problems to be Solved by the Invention】 【0003】 According to specific designs of such aerosol generating systems, the article may have a cylindrical stick shape, similar to the shape of a conventional cigarette, with the susceptor and substrate disposed in the distal end portion, for example, within the distal substrate plug, and the mouthpiece disposed in the proximal end portion of the article. Aerosol generating articles having such visual and tactile similarities to conventional cigarettes are mainly known for articles comprising a solid aerosol-forming substrate, particularly a tobacco-containing solid aerosol-forming substrate. Systems using other substrates, such as so-called e-liquids, typically employ a different design for the entire system for technical reasons. However, in order to expand the range of products compatible with the aforementioned devices configured to receive and inductively heat a stick-shaped article, it is desirable for articles using other aerosol-generating substrates, particularly liquid substrates, to have a similar but simpler design. [Brief explanation of the drawing] 【0004】 [Figure 1] The general structure and components of the aerosol-generating article according to the present invention are schematically shown. [Figure 2] This shows an aerosol-generating article according to the first embodiment of the present invention. [Figure 3] The aerosol generation system according to the present invention is shown, comprising an induction heating aerosol generator and an aerosol generating article as shown in Figure 2. [Figure 4] Figure 2 shows details of the cartridge used in the aerosol generating article according to the embodiment. [Figure 5] Figure 2 shows details of the cartridge used in the aerosol generating article according to the embodiment. [Figure 6] Figure 2 shows details of the cartridge used in the aerosol generating article according to the embodiment. [Figure 7] Figure 2 shows details of the cartridge used in the aerosol generating article according to the embodiment. [Figure 8] Figure 2 shows details of a second embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 9] Figure 2 shows details of a second embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 10] Figure 2 shows details of a second embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 11] Figure 2 shows details of a second embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 12] Figure 2 shows details of a third embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 13] Figure 2 shows details of a third embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 14] Figure 2 shows details of a fourth embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 15] Figure 2 shows details of a fourth embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Figure 16] Figure 2 shows details of a fourth embodiment of a cartridge that can be used as an alternative to the aerosol generating article. [Modes for carrying out the invention] 【0005】 According to the present invention, a cartridge for a stick-shaped aerosol generating article for use with an induction heating aerosol generating device is provided, i.e., a cartridge for a stick-shaped aerosol generating article, i.e., a cartridge for use with a stick-shaped aerosol generating article, the article being configured for use with an induction heating aerosol generating device. The cartridge includes a vaporization chamber at the distal end of the cartridge for vaporizing an aerosol-forming liquid therein, and a storage chamber proximal to the vaporization chamber for storing the aerosol-forming liquid. The cartridge further includes a liquid transport susceptor arrangement configured and arranged to be induction heated when used with the device for transporting the aerosol-forming liquid from the storage chamber into the vaporization chamber and vaporizing the aerosol-forming liquid in the vaporization chamber. The cartridge further includes a vapor transport conduit providing fluid communication for the vaporized aerosol-forming liquid from the vaporization chamber to the proximal region of the storage chamber. In addition, the cartridge includes a proximal end cap that forms at least the proximal end wall member of the storage chamber, the proximal end cap includes a through hole through which the proximal end portion of a steam transport conduit passes, is supported within it, or terminates integrally within it. 【0006】 According to the present invention, the above-described design of the cartridge has been found to be advantageous for the simple and cost-effective manufacture of stick-shaped aerosol generating articles that can be easily used with induction heating aerosol generators already intended for solid substrate consumables, in order to generate aerosols from liquid substrates as well. As will be described in more detail below, such articles can be easily realized, for example, by equipping the cartridge with a cylindrical mouthpiece adjacent to a storage chamber, and then wrapping a wrapper around at least a portion of the cartridge and around the mouthpiece to hold the mouthpiece and cartridge together. This results in an article having a stick-like outer shape similar to or equal to already intended articles containing a solid substrate, and therefore suitable for use with already intended aerosol generators. For this reason, these devices can generally be used with different types of articles to generate aerosols from different types of aerosol-forming substrates, in particular solid substrates and liquid substrates. 【0007】 Placing a vaporization chamber at the distal end of the cartridge, and therefore at the distal end of the article containing such a cartridge, corresponds to placing a solid substrate and susceptor at the distal substrate plug of the already intended article. Advantageously, this ensures that, when used with an induction heating aerosol generator, the vaporization chamber is positioned within the device's cavity at approximately the same location as the distal substrate plug of the already intended article, i.e., where an alternating magnetic field is generated within the cavity. Thus, articles containing such cartridges are not only receptive but also readily heatable by these existing devices for induction heating consumables containing a solid aerosol-forming substrate. 【0008】 The use of a proximal end cap is advantageous in that it may allow other components of the cartridge, such as the steam transport conduit or the circumferential outer walls of the storage chamber and vaporization chamber, to be manufactured by extrusion, thereby facilitating the manufacture of the cartridge. Having a proximal end portion of the steam transport conduit passing through a through-hole in the proximal end cap, or being supported within it, or integrally terminating within it, proves advantageous in terms of stable fixation of the steam transport conduit within the cartridge, as well as in terms of proper sealed fitting between the steam transport conduit and the proximal end cap. 【0009】 Proper sealing is particularly important when the vapor transport conduit also forms a wall member of the storage chamber. For example, the vapor transport conduit may be formed by an inner tube of the cartridge, which provides fluid communication from the vaporization chamber to the proximal region of the storage chamber internally, and defines the inner side wall member of the storage chamber externally. In this configuration, both the proximal end cap and the vapor transport conduit form a wall member of the storage chamber, and for this reason, the joint between the two components must be properly sealed to prevent leakage of aerosol-forming liquid. A particularly appropriate sealing is automatically provided when the proximal end of the vapor transport conduit terminates integrally within a through hole, i.e., at least a portion of the vapor transport conduit, preferably the entire vapor transport conduit, is integrally formed with the proximal end cap. 【0010】 As described above, the proximal end cap forms at least the proximal wall member of the storage chamber. In particular, the proximal end cap may form only the proximal wall member of the storage chamber. Therefore, the proximal end cap may be non-integrated (separate) from any other wall member of the storage chamber, such as the circumferential outer wall member or the inner side wall member of the storage chamber. Similarly, the proximal end cap may be non-integrated (separate) from the steam transport conduit, in particular when the steam transport conduit forms the wall member (inner wall member) of the storage chamber. That is, the proximal end cap may be separate from any wall member of the storage chamber other than the proximal end wall member. Conversely, in addition to the proximal wall member of the storage chamber, the proximal end cap also forms at least one of the circumferential outer wall member or the inner side wall member of the storage chamber. In this configuration, the proximal end cap may correspond to a part of the integrated body described in detail below. Also, the proximal end cap may be non-integrated (separate) from any wall member of the vaporization chamber. 【0011】 The proximal end cap may include a distal recess that forms the distal portion of the through-hole, internally supporting the proximal end portion of the steam transport conduit. The inner cross-section of the distal recess may be larger than the inner cross-section of the proximal portion of the through-hole other than the distal portion. Thus, the distal recess forms a contact portion with the proximal end portion of the steam transport conduit for fixing the position of the steam transport conduit at least in the proximal direction. Furthermore, the inner cross-section of the proximal portion of the through-hole may correspond to the inner cross-section of the steam transport conduit. As a result, the airflow passage through the steam transport conduit is smoothly continuous through the proximal portion of the through-hole, which is advantageous with respect to turbulent airflow / aerosol flow through the cartridge. Alternatively, the inner cross-section of the proximal portion of the through-hole may be larger or smaller than the inner cross-section of the steam transport conduit. As a result, the airflow passage through the cartridge may not be smooth, and the airflow / aerosol flow may be turbulent. Turbulent airflow / aerosol flow may be desirable to promote aerosol formation. 【0012】 The proximal end cap may include a distal insertion socket projecting into the storage chamber, forming the distal portion of the through-hole, in which the proximal end portion of the steam transport conduit is internally supported. That is, the distal insertion socket can be considered a projection extending into the storage chamber, including a recess that forms the distal portion of the through-hole. The inner cross-section of the distal insertion socket may be larger than the inner cross-section of the proximal portion of the through-hole other than the distal portion. Thus, as described above with respect to the distal recess, the distal insertion socket forms a contact portion with respect to the proximal end portion of the steam transport conduit for fixing the position of the steam transport conduit at least in the proximal direction. To provide a substantially smooth airflow passage through the cartridge, the inner cross-section of the proximal portion of the through-hole may correspond to the inner cross-section of the steam transport conduit. Alternatively, the inner cross-section of the proximal portion of the through-hole may be larger or smaller than the inner cross-section of the steam transport conduit to promote turbulent / aerosol flow. 【0013】 The proximal end cap may include at least one filling hole for filling the storage chamber with aerosol-forming liquid. The filling hole in the proximal end cap provides easy access to the interior of the associated chamber for filling. To close at least one filling hole as the storage chamber is filled with aerosol-forming liquid, the cartridge may include a proximal plug member that seals at least one filling hole in the proximal end cap. If the proximal end cap includes two or more filling holes, the proximal plug member is preferably configured to close each of the filling holes. Alternatively, the cartridge may include separate proximal plug members for each of the filling holes. To have a substantially flat proximal surface at the proximal end of the cartridge, the proximal end cap may include a proximal recess into which the proximal plug member is received. One or more filling holes may be arranged adjacent to a through hole in the proximal end cap. For example, the proximal end cap may include two filling holes arranged transversely on opposing sides of a through hole. In this configuration, the proximal plug member may include a disc having a projection that tightly fits into the filling hole. To allow the aerosol to escape freely proximal to the cartridge, the proximal plug member may include a through-hole that matches the through-hole of the proximal end cap. The cross-section of the through-hole of the proximal plug member preferably corresponds to the inner cross-section of the vapor transport conduit to provide a smooth airflow passage. Alternatively, the cross-section of the through-hole of the proximal plug member may be larger or smaller than the inner cross-section of the vapor transport conduit to promote turbulent / aerosol flow. 【0014】 According to one embodiment, the proximal end cap may be in the form of a plug. The plug-shaped proximal end cap may include a plug body at least a portion of which is inserted into the circumferential outer wall member of the storage chamber. The plug body may also be fully inserted into the circumferential outer wall of the storage chamber. Generally, the plug body may have a shape corresponding to the shape inside the storage chamber, particularly, a cross-sectional shape corresponding to the cross-sectional shape inside the storage chamber. As used herein, the term "cross-sectional shape" refers to the shape inside the plug body or the storage chamber as seen in a cross-section orthogonal to the longitudinal axis of the cartridge. The plug body is preferably substantially cylindrical or frustoconical. The plug body may also include a circumferential collar that provides a sealed fit of the proximal end cap within the cartridge, particularly to the circumferential outer wall member of the storage chamber. That is, the circumferential collar is not inserted into the circumferential outer wall member of the storage chamber. 【0015】 The plug-shaped proximal end cap may also include a cover plate. To completely close the storage chamber at the proximal end of the cartridge, the cover plate may either be inserted into the circumferential outer wall of the storage chamber or extend radially outward beyond the cross-sectional shape inside the storage chamber. In the latter case, the cover plate may further include a protruding collar that abuts the proximal front end of the circumferential outer wall member of the storage chamber. This also generally applies to the plug-shaped proximal end cap, i.e., the plug-shaped proximal end cap may include a protruding collar that abuts the proximal front end of the circumferential outer wall member of the storage chamber. 【0016】 The plug-shaped proximal end cap may further preferably include, in addition to the cover plate, an insertion portion that is at least partially inserted into the circumferential outer wall member of the storage chamber. The insertion portion may include an insertion ring, or insertion tube, or insertion cylinder, or hollow insertion cylinder, or multiple insertion ring segments, or multiple insertion pins, or multiple insertion fins. The insertion portion may extend at least partially, in particular from the cover plate (if present) to the septum that forms a common wall member of the vaporization chamber and the storage chamber. This also generally applies to the plug-shaped proximal end cap, i.e., the plug-shaped proximal end cap may extend at least partially, in particular from the cover plate (if present) to the septum that forms a common wall member of the vaporization chamber and the storage chamber. In particular, the plug-shaped proximal end cap may include at least one, particularly at least two, preferably two, three, or four support legs. At least one support leg may extend preferably from the proximal end of the cartridge, particularly from the cover plate (if present) to the septum that forms a common wall member of the vaporization chamber and the storage chamber. Therefore, the plug-shaped proximal end cap is fixed in place at least distal to the septum. At least two, and especially two, three, or four, support legs are advantageous in providing uniform support for the proximal end cap to the septum. The septum is described in more detail below. In particular, at least one support leg may extend along the inner surface of the circumferential outer wall member of the storage chamber. 【0017】 According to another embodiment, the proximal end cap may be cup-shaped. In particular, the cup-shaped proximal end cap may include a bottom portion forming the proximal end wall member of the storage chamber and a sleeve portion (the side wall of the cup shape) forming the circumferential outer wall member of the storage chamber. In this configuration, the storage chamber is substantially completely formed by the proximal end cap, except for the distal end wall member of the vaporization chamber. The distal end wall member is preferably formed by the aforementioned septum. By having a circumferential outer wall member and a proximal end wall member of the storage chamber integrally formed by a cup-shaped proximal end cap, i.e., formed by an integral component, advantageously, the number of components to be assembled is reduced, and thus, the structure and assembly of the cartridge are simplified. 【0018】 Generally, especially when the proximal end cap is separated (non-integral) from any other wall member of the storage chamber, the proximal end cap may be attached into the cartridge by press fitting, or snap fitting, or welding, or adhesive bonding. Press fitting or snap fitting enables particularly simple assembly of the proximal end cap. Welding or adhesive bonding ensures good sealing of the joint between the proximal end cap and the corresponding connection portion. When the proximal end cap is plug-shaped or includes a cover plate (with or without an insertion portion), the proximal end cap may be attached (as a connection portion) to the circumferential outer wall member of the storage chamber, particularly to the distal end of the circumferential outer wall member of the storage chamber (preferably by any of the means described above). When the proximal end cap is cup-shaped, the proximal end cap may be attached (as a corresponding connection portion) to the septum of the cartridge (preferably by any of the above), and the septum forms the common wall member of the storage chamber and the storage chamber, particularly the distal end wall member of the vaporization chamber. 【0019】 The proximal end cap is preferably made of a material that cannot be inductively heated, i.e., a non-conductive and non-magnetic (non-ferromagnetic or non-ferromagnetic) material. The proximal end cap may be made of plastic or silicone. Such materials provide suitable sealing properties and are inexpensive, which is particularly important in relation to the fact that the cartridge is used in aerosol generating articles which are preferably configured for single use only. Preferably, the plastic is thermoplastic, such as PEEK (polyether ether ketone), to provide good thermal stability. The proximal end cap may be manufactured by injection molding; that is, the proximal end cap may be an injection-molded proximal end cap. 【0020】 The proximal end cap preferably defines the nearest end of the cartridge. That is, there are no other components that protrude proximally beyond the proximal end cap. In particular, the proximal end of the cartridge may not include any connectors or connecting means, such as those for connecting a mouthpiece to the cartridge. For example, if a stick-shaped cartridge has a cylindrical shape, the cartridge may have a flat proximal surface at its nearest end. 【0021】 Similar to the proximal end cap, the cartridge may include a distal end cap that forms at least the distal wall member of the vaporization chamber. Preferably, the distal end cap is not integrated with any wall member of the storage chamber. The use of a distal end cap also has the advantage of facilitating the manufacture of the cartridge. In particular, it allows for the implementation of open access to components located inside the cartridge, such as liquid transport susceptor arrangements, before the inside of the cartridge is finally closed by the distal end cap. 【0022】 Preferably, the vaporization chamber may be completely enclosed by a wall member. Thus, the vaporization chamber is substantially sealed except for one possible air intake and fluid communication from the vaporization chamber to the proximal region of the storage chamber. As a result, the cartridge is substantially leak-proof, which is advantageous with respect to the shelf life of the article to which the cartridge may be part. In particular, if, for example, during transport from manufacturing to sale, the aerosol-forming liquid eventually leaks from the storage chamber into the vaporization chamber, the liquid will still be retained within the vaporization chamber. Furthermore, the liquid leaked into the vaporization chamber is not wasted but still evaporates during the next heating process, thus contributing to aerosol generation. In this respect, the term “chamber” as used herein already implies a substantially sealed chamber. Therefore, the storage chamber is also substantially sealed except for fluid communication between the storage chamber and the vaporization chamber via the liquid transport susceptor arrangement. 【0023】 To prevent users from being burned by touching an article containing the cartridge according to the present invention immediately after the heating process, the distal end cap is preferably non-inductively heatable. Furthermore, this prevents the energy provided by the alternating magnetic field from being unnecessarily dissipated within the distal end cap. As a result, energy dissipation in the liquid transport susceptor configuration may be enhanced. Therefore, the distal end cap is preferably made of a non-inductively heatable material, i.e., a non-conductive and non-magnetic (non-ferromagnetic or non-ferromagnetic) material. The distal end cap may be made of plastic or silicone. Such materials provide suitable sealing properties and are inexpensive, which is particularly important in relation to the fact that the cartridge is used in an aerosol generating article preferably configured for single use only. Preferably, the plastic is thermoplastic, such as PEEK (polyether ether ketone), to provide good thermal stability. The distal end cap may be manufactured by injection molding. That is, the distal end cap may be an injection-molded distal end cap. 【0024】 Preferably, all wall members of the vaporization chamber are non-inductively heatable, i.e., made from a non-inductively heatable material. Similarly, any wall member of the vaporization chamber is also non-inductively heatable. 【0025】 The distal end cap preferably defines the most distal end of the cartridge. That is, there are no other components that protrude distally beyond the distal end cap. In particular, the distal end of the cartridge may not include any connectors or connecting means for connecting the aerosol generating article containing such a cartridge to an aerosol generating device. For example, if a stick-shaped cartridge has a cylindrical shape, the cartridge may have a flat distal surface at its most distal end. 【0026】 To allow air to enter the vaporization chamber for aerosol formation, the vaporization chamber may include at least one air intake. Preferably, at least one air intake is formed within the distal end cap. As an example, at least one air intake may include a vent hole passing through the distal end cap. As another example, at least one air intake may include a vent groove formed on the surface of the distal end cap facing the wall members of the vaporization chamber other than the distal end cap, particularly within the circumferential outer wall member of the vaporization chamber. 【0027】 In one embodiment, the distal end cap may be plug-shaped. A plug-shaped distal end cap may include a plug body, at least a portion of which is inserted into the circumferential outer wall member of the vaporization chamber. The plug body may also be fully inserted into the circumferential outer wall member of the vaporization chamber. Generally, the plug body may have a shape corresponding to the internal shape of the vaporization chamber, in particular a cross-sectional shape corresponding to the internal cross-sectional shape of the vaporization chamber. As used herein, the term “cross-sectional shape” refers to the shape of the plug body or the internal shape of the vaporization chamber as seen in a cross-section perpendicular to the longitudinal axis of the cartridge. The plug body is preferably substantially cylindrical or frustoconical. The plug body may include a circumferential collar within the cartridge, in particular, that provides a sealed fit of the distal end cap to the circumferential outer wall member of the storage chamber. That is, the circumferential collar is not inserted into the circumferential outer wall of the vaporization chamber. 【0028】 A plug-shaped distal end cap may also include a cover plate. To completely close the vaporization chamber at the distal end of the cartridge, the cover plate may either be inserted into the circumferential outer wall of the vaporization chamber or extend radially outward beyond the cross-sectional shape inside the vaporization chamber. In the latter case, the cover plate may further include a projecting collar that abuts against the distal front end of the circumferential outer wall member of the vaporization chamber. This also generally applies to plug-shaped distal end caps, i.e., a plug-shaped distal end cap may include a projecting collar that abuts against the distal front end of the circumferential outer wall member of the vaporization chamber. 【0029】 The plug-shaped distal end cap may further preferably include, in addition to the cover plate, an insertion portion that is at least partially inserted into the circumferential outer wall member of the vaporization chamber. The insertion portion may include an insertion ring, or insertion tube, or insertion cylinder, or hollow insertion cylinder, or multiple insertion ring segments, or multiple insertion pins, or multiple insertion fins. The insertion portion may extend at least partially from the cover plate (if present) to a septum that forms a common wall member of the vaporization chamber and the storage chamber. This also generally applies to the plug-shaped distal end cap, i.e., the plug-shaped distal end cap may extend at least partially from the cover plate (if present) to a septum that forms a common wall member of the vaporization chamber and the storage chamber. In particular, the plug-shaped distal end cap may include at least one, particularly at least two, preferably two, three, or four support legs. At least one support leg may extend preferably from the distal end of the cartridge, particularly from the cover plate (if present), to a septum that forms a common wall member of the vaporization chamber and the storage chamber. Therefore, the plug-shaped distal end cap is fixed in place at least proximal to the septum. At least two, and especially two, three, or four, support legs are advantageous in providing uniform support for the distal end cap to the septum. The septum is described in more detail below. In particular, at least one support leg may extend along the inner surface of the circumferential outer wall member of the vaporization chamber. Thus, the aerosol formation process inside the vaporization chamber is only slightly affected. 【0030】 Furthermore, the plug-shaped distal end cap may include at least one plug member at its proximal end to seal a filling hole in the septum, which can be used to fill the storage chamber with aerosol-forming liquid via the vaporization chamber. Advantageously, this configuration allows sealing the filling hole and closing the distal end of the vaporization chamber to be performed in a single step by attaching the plug-shaped distal end cap to the other parts of the cartridge. Preferably, the plug member is located at the proximal end of the insertion portion (if any), particularly at the proximal end of at least one support leg (if any). The plug member may be made of the same material as the other parts of the plug-shaped distal end cap, or in particular, may be integral with them. 【0031】 In another embodiment, the distal end cap may be cup-shaped. In particular, a cup-shaped distal end cap may include a bottom portion that forms the distal end wall member of the vaporization chamber and a sleeve portion (cup-shaped side wall) that forms the circumferential outer wall member of the vaporization chamber. In this configuration, the vaporization chamber is substantially entirely formed by the distal end cap, except for the proximal end wall member of the vaporization chamber. The proximal end wall member of the vaporization chamber is preferably formed by the septum described above. Having the circumferential outer wall member and distal end wall member of the vaporization chamber integrally formed by the cup-shaped distal end cap, i.e., formed by a single component, is advantageous because it reduces the number of components to assemble, and therefore simplifies the structure and assembly of the cartridge. Furthermore, this configuration provides maximum open access for mounting components inside the cartridge, such as for the placement of a liquid transport susceptor. 【0032】 Generally, the distal end cap may be attached to the cartridge by press fitting, snap fitting, welding, or adhesive bonding. Press fitting or snap fitting allows for particularly simple assembly of the distal end cap. Welding or adhesive bonding ensures good sealing of the joint between the distal end cap and the corresponding connector. If the distal end cap is plug-shaped or includes a cover plate (with or without an insertion portion), the distal end cap may be attached (preferably by any of the means described above) to the circumferential outer wall member of the vaporization chamber, particularly to the distal end of the circumferential outer wall member of the vaporization chamber (as the corresponding connector). If the distal end cap is cup-shaped, the distal end cap may be attached (preferably by any of the means described above) to the septum of the cartridge (as the corresponding connector), which forms a common wall member of the vaporization chamber and storage chamber, particularly the proximal end wall member of the vaporization chamber. 【0033】 The cartridge may include a septum that forms a common wall member of the vaporization chamber and the storage chamber. Using a septum that forms a common wall member of the vaporization chamber and the storage chamber is advantageous because it reduces the number of components to be assembled, thus simplifying the structure and assembly of the cartridge. Preferably, the septum is non-integrated (separate) from any other wall members of the vaporization chamber and the storage chamber. Advantageously, this facilitates the manufacture of the cartridge, as it may allow other components of the cartridge, such as the steam transport conduit or the circumferential outer walls of the storage chamber and the vaporization chamber, to be manufactured by extrusion. 【0034】 In this specification, the term "septum" means a separation wall that separates the vaporization chamber from the storage chamber, that is, a separation wall that separates a portion of the inside of the cartridge into the vaporization chamber and the storage chamber. 【0035】 To prevent the energy provided by the alternating magnetic field from being unnecessarily dissipated within the septum, it is preferable that the septum be non-inductively heatable. That is, it is preferable that the septum be made of a non-inductively heatable material, i.e., a non-conductive and non-magnetic (non-ferromagnetic or non-ferromagnetic) material. In addition, this may help reduce the risk of burns to the user when touching an article containing the cartridge according to the present invention immediately after the heating process. 【0036】 The septum may be made of plastic or silicone. These materials provide suitable sealing properties and are inexpensive, which is particularly important in relation to the fact that the cartridge is used in aerosol-generating articles, which are preferably configured for single use only. Preferably, the plastic is thermoplastic, such as PEEK (polyether ether ketone), to provide good thermal stability. The septum may be manufactured by injection molding; that is, the septum may be an injection-molded septum. 【0037】 The septum preferably includes a through-hole through which the steam transport conduit passes or is supported at its distal end. 【0038】 The septum may include a proximal recess that forms the proximal portion of a through-hole supported within the distal end of the steam conduit. The inner cross-section of the proximal recess may be larger than the inner cross-section of the distal portion of the through-hole other than the proximal portion. Thus, the proximal recess forms a contact portion with the distal end of the steam conduit for fixing the position of the steam conduit at least in the distal direction. Furthermore, the inner cross-section of the distal portion of the through-hole may correspond to the inner cross-section of the steam conduit. As a result, the airflow passage entering the steam conduit through the septum's through-hole can be smoothly continuous from the vaporization chamber into the steam conduit. This is advantageous with respect to turbulent airflow / aerosol flow through the cartridge. Alternatively, the inner cross-section of the distal portion of the through-hole may be larger or smaller than the inner cross-section of the steam conduit. As a result, the airflow passage through the cartridge may not be smooth, and the airflow / aerosol flow may be turbulent. Turbulent airflow / aerosol flow may be desirable to promote aerosol formation. 【0039】 The septum may include a proximal insertion socket projecting into the storage chamber, which forms the proximal portion of the through-hole, supporting the distal end portion of the steam conduit internally. That is, the proximal insertion socket can be considered a projection extending into the storage chamber, including a recess that forms the proximal portion of the through-hole. The inner cross-section of the proximal insertion socket may be larger than the inner cross-section of the distal portion of the through-hole other than the proximal portion. Thus, as described above with respect to the proximal recess, the proximal insertion socket forms a contact portion with the distal end portion of the steam conduit for fixing the position of the steam conduit at least in the distal direction. To provide a substantially smooth airflow passage through the cartridge, the inner cross-section of the distal portion of the through-hole may correspond to the inner cross-section of the steam conduit. Alternatively, the inner cross-section of the distal portion of the through-hole may be larger or smaller than the inner cross-section of the steam conduit to promote turbulent / aerosol flow. 【0040】 The liquid transport susceptor configuration preferably passes through the septum. Therefore, the septum may include one or more feedthrough openings through which the liquid transport susceptor configuration passes. The liquid transport susceptor configuration is preferably fixedly held by the septum. Advantageously, the liquid transport susceptor configuration is fixed to the septum before the cartridge is assembled to facilitate assembly. 【0041】 To prevent leakage of undesirable aerosol-forming liquid, the cartridge may be provided with at least one sealing ring for each of the one or more feedthrough openings in the septum disposed within or within each of the feedthrough openings. In particular, at least one sealing ring may be overmolded around a portion of the liquid transport susceptor arrangement. Advantageously, this provides particularly good sealing and facilitates the assembly of the cartridge. It is preferable that the liquid transport susceptor arrangement is overmolded with the sealing ring before the cartridge is assembled. At least one sealing ring is preferably made of plastic or silicone. Such materials provide good sealing properties and are inexpensive, which is particularly important in relation to the fact that the cartridge is used in aerosol-generating articles which are preferably configured for single use only. Preferably, the plastic is thermoplastic, such as PEEK (polyether ether ketone), to provide good thermal stability. 【0042】 The septum may include at least one filling hole for filling the storage chamber with aerosol-forming liquid via a vaporization chamber. One or more filling holes may be located adjacent to a through-hole in the septum, through which a vapor transport conduit passes or is supported therein at its distal end portion. For example, the septum may include two filling holes located transversely on opposite sides of a through-hole. To close at least one filling hole as the storage chamber is filled with aerosol-forming liquid, the cartridge may include a distal plug member that seals at least one filling hole in the septum. If the septum includes two or more filling holes, the distal plug member is preferably configured to close each of the filling holes. Alternatively, the cartridge may have separate distal plug members for each of the filling holes. Preferably, the distal plug member is attached to a distal end cap that forms at least the distal end wall member of the vaporization chamber, and is particularly preferably an integral part with the distal end cap. Details of the distal end cap are described above. Alternatively, the distal plug member may be independent of any wall member of the vaporization chamber. Similarly, the distal plug member may be independent of any wall member of the storage chamber. Like the septum itself, the distal plug member may be made of plastic or silicone, particularly PEEK (polyether ether ketone), to provide good thermal stability. 【0043】 The septum may be mounted within the cartridge by press fitting, snap fitting, welding, or adhesive bonding. Press fitting or snap fitting allows for particularly simple assembly of the septum. Welding or adhesive bonding ensures good sealing of the joint between the septum and the corresponding connection. The septum is preferably mounted within a cartridge sleeve that forms at least one circumferential outer wall member of the vaporization chamber (or at least a portion thereof) and the circumferential outer wall member of the storage chamber (or at least a portion thereof). Similarly, the septum may be mounted within an outer sleeve portion of the integrated body of the cartridge, forming at least the circumferential outer wall member of the storage chamber, and preferably the circumferential outer wall member of the vaporization chamber. Further details of the cartridge sleeve and integrated body are described below. The cartridge may also be equipped with a cup-shaped distal end cap and a cup-shaped proximal end cap, the cup-shaped distal end cap forming the distal end wall and circumferential outer wall of the vaporization chamber, and the cup-shaped proximal end cap forming the proximal end wall and circumferential outer wall of the storage chamber. In this configuration, each of the cup-shaped end caps is attached to the septum such that the septum holds the cup-shaped distal end cap and the cup-shaped proximal end cap together, forming the distal end wall of the storage chamber and the proximal end wall of the vaporization chamber. Details of the cup-shaped distal end cap and the cup-shaped proximal end cap have already been described above. 【0044】 The septum may include a circumferential collar that provides a sealed fit for the septum within the cartridge. In particular, the septum may include a circumferential collar that provides a sealed fit for the septum with respect to the cartridge sleeve forming at least one of the outer peripheral wall members of the vaporization chamber and the outer peripheral wall members of the storage chamber, or with respect to the outer sleeve portion, or with respect to at least one of the cup-shaped distal end cap and the cup-shaped proximal end cap, as described above. 【0045】 The cartridge may include a cartridge sleeve. The cartridge sleeve may form at least one of the circumferential outer wall members of the vaporization chamber (or at least a portion thereof) and the circumferential outer wall members of the storage chamber (or at least a portion thereof). In particular, the cartridge sleeve may extend along the entire axial extension of the storage chamber and the vaporization chamber, i.e., preferably along the entire axial extension of the cartridge. 【0046】 The cartridge sleeve may have an inner and outer cross-section of any shape. In particular, the cartridge sleeve may have an inner cross-section that is circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal. Similarly, the cartridge sleeve may have an outer cross-section that is circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal. 【0047】 The cartridge sleeve may be tubular, particularly cylindrical, or cylindrical tube. Tubular sleeves, especially cylindrical sleeves or cylindrical tubes, are particularly easy to manufacture by extrusion molding. Therefore, the cartridge sleeve may be an extruded cartridge sleeve. 【0048】 Preferably, the cartridge sleeve is made of a material that cannot be inductively heated, i.e., a non-conductive and non-magnetic (non-ferromagnetic or non-ferromagnetic) material. For example, the cartridge sleeve may be made of plastic or silicone. Preferably, the plastic is thermoplastic, such as PEEK (polyether ether ketone), to provide good thermal stability. 【0049】 The cartridge sleeve may be combined with a distal end cap that can be attached to the distal end of the cartridge sleeve, as described above. Similarly, the cartridge sleeve may be combined with a proximal end cap that can be attached to the proximal end of the cartridge sleeve, as described above. In particular, the distal end cap may be attached to the distal end of the cartridge sleeve by press fitting, snap fitting, welding, or adhesive bonding. Similarly, the proximal end cap may be attached to the proximal end of the cartridge sleeve by press fitting, snap fitting, welding, or adhesive bonding. 【0050】 When the cartridge sleeve forms only the circumferential outer wall member of the vaporization chamber, or the circumferential outer wall member of both the vaporization chamber and the storage chamber, the distal end cap is preferably plug-shaped or includes a cover plate (with or without an insertion portion), as described above. In this configuration, the distal end cap forms the distal end wall member of the vaporization chamber. 【0051】 When the cartridge sleeve forms only the circumferential outer wall member of the storage chamber, the distal end cap is preferably cup-shaped as described above. In this configuration, the distal end cap forms both the distal end wall member and the circumferential outer wall member of the vaporization chamber. 【0052】 Similarly, if the cartridge sleeve forms only the circumferential outer wall member of the storage chamber, or the circumferential outer wall member of both the vaporization chamber and the storage chamber, the proximal end cap is preferably plug-shaped or includes a cover plate (with or without an insertion portion), as described above. In this configuration, the proximal end cap forms the proximal end wall member of the storage chamber. 【0053】 When the cartridge sleeve forms only the circumferential outer wall member of the vaporization chamber, the proximal end cap is preferably cup-shaped as described above. In this configuration, the proximal end cap forms both the proximal end wall member and the circumferential outer wall member of the storage chamber. 【0054】 It is preferable that the cartridge sleeve is not integrated with (separated from) the distal end cap. Similarly, it is preferable that the cartridge sleeve is not integrated with (separated from) the proximal end cap. 【0055】 To reduce the number of components to be assembled, the cartridge may comprise a single body including a proximal end portion and at least one of an outer sleeve portion and an inner tube portion, the outer sleeve portion forming the circumferential outer wall member of the storage chamber (or at least a portion thereof), the proximal end portion forming the proximal end wall member of the storage chamber, and the inner tube portion forming the steam transport conduit (or at least a portion thereof). The inner tube portion is disposed particularly coaxially within the outer sleeve portion and therefore within the inner wall member of the storage chamber. The proximal end portion may include a through hole into which the proximal end of the inner tube portion of the steam transport conduit, particularly the proximal end of the inner tube portion, opens inward. Preferably, the single body comprises the proximal end portion and both the outer sleeve portion and the inner tube portion. Advantageously, the outer sleeve portion may also form the circumferential outer wall member of the vaporization chamber (or at least a portion thereof). Advantageously, such a single body simplifies the construction and assembly of the cartridge. The proximal end portion may correspond to the aforementioned proximal end cap, which forms the proximal end wall member of the storage chamber. 【0056】 In particular, the outer sleeve portion may extend along the entire axial length extension of the storage chamber. Alternatively, the outer sleeve portion may extend along the entire axial length extension of the storage chamber and the vaporization chamber, i.e., preferably along the entire axial length extension of the cartridge. The inner tube portion may extend along the entire axial length extension of the storage chamber, in particular between the proximal end portion and the septum that forms a common wall member of the storage chamber and the vaporization chamber. The distal end of the inner tube portion may preferably be attached to the septum by press fitting, snap fitting, welding, or adhesive bonding. Similarly, the septum may preferably be attached to the outer sleeve portion by press fitting, snap fitting, welding, or adhesive bonding. The outer sleeve portion may have an inner cross-section of circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal shape, and an outer cross-section of circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal shape. Similarly, the inner tube portion may have an inner cross-section that is circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal, and an outer cross-section that is circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal. 【0057】 The integrated body is preferably combined with a distal end cap, as detailed above. That is, the integrated body is not integrated with (separates from) the distal end cap. The distal end cap may be attached to the distal end of the integrated body, in particular by press fitting, snap fitting, welding, or adhesive bonding. When the outer sleeve portion forms the circumferential outer wall members of both the vaporization chamber and the storage chamber, the distal end cap is preferably plug-shaped or includes a cover plate (with or without an insertion portion), as described above. In this configuration, the distal end cap forms the distal end wall member of the vaporization chamber. When the outer sleeve portion forms only the circumferential outer wall member of the storage chamber, the distal end cap is preferably cup-shaped, as described above. In this configuration, the distal end cap forms both the distal end wall member of the vaporization chamber and the circumferential outer wall member of the vaporization chamber. Preferably, the integrated body is made of a material that cannot be inductively heated, i.e., a non-conductive and non-magnetic (non-ferromagnetic or non-ferromagnetic) material. For example, the integrated body may be made of plastic or silicone. Preferably, the plastic is thermoplastic, such as PEEK (polyether ether ketone), to provide good thermal stability. The integrated body may be manufactured by injection molding. That is, the integrated body may be an injection-molded integrated body. 【0058】 The steam transport conduit may be disposed within the circumferential outer wall member of the storage section member. If the circumferential outer wall member of the storage section member is formed by a cartridge sleeve as described above, the steam transport conduit may be disposed within the cartridge sleeve, and in particular coaxially with respect to the cartridge sleeve. 【0059】 As described above, it is preferable that the steam transport conduit forms the inner side wall member of the storage chamber. Furthermore, the steam transport conduit forming the inner side wall member of the storage chamber enables a very compact design for the cartridge. In this configuration, the volume of the storage chamber may be substantially ring-shaped, particularly hollow cylindrical. 【0060】 The steam transport conduit may extend along the axial length extension of the storage chamber, in particular between the proximal end and the distal end of the storage chamber, and more specifically between the proximal end cap (as described above) and the septum that forms a common wall member of the storage chamber and the vaporization chamber. 【0061】 In particular, the cartridge may include an inner tube that forms a steam transport conduit. Specifically, the inner tube may be similar to the inner tube portion of the integrated body described above, but may be separated from any other wall members of the storage chamber, such as the proximal end cap and septum. That is, the inner tube is preferably not integrated with any wall members of the storage chamber other than the circumferential inner wall members of the storage chamber. 【0062】 The inner tube may extend along the entire axial length extension of the storage chamber, particularly between the proximal end cap and the septum, which forms a common wall member of the storage chamber and the vaporization chamber. The distal end of the inner tube may be attached to the septum, for example, to the proximal recess or proximal insertion socket of the septum. Similarly, the proximal end of the inner tube may be attached to the proximal end cap, for example, to the distal recess or distal insertion socket of the proximal end cap. The inner tube is preferably attached to the septum and proximal end cap by press fitting, snap fitting, welding, or adhesive bonding. 【0063】 The steam transport conduit, particularly the inner tube, may be cylindrical. The cylindrical shape is particularly easy to manufacture, especially by extrusion molding. Therefore, the steam transport conduit may be an extruded steam transport conduit. In particular, the inner tube may be an extruded inner tube. 【0064】 Steam transport conduits, particularly inner tubes, may have circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal inner cross-sections. Similarly, steam transport conduits, particularly inner tubes, may have circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal outer cross-sections. 【0065】 Preferably, the steam transport conduit, particularly the inner tube, is made of a material that cannot be inductively heated, i.e., a non-conductive and non-magnetic (non-ferromagnetic or non-ferromagnetic) material. For example, the cartridge sleeve may be made of plastic or silicone. Preferably, the plastic is thermoplastic, such as PEEK (polyether ether ketone), to provide good thermal stability. 【0066】 As used herein, the term “liquid transport susceptor arrangement” refers to a susceptor arrangement having the ability to perform two functions: transporting and heating an aerosol-forming liquid. Similarly, a liquid transport susceptor arrangement can be considered an inductively heated liquid conduit. By using such a liquid transport susceptor arrangement, the number of required components is reduced and thus the manufacture of the cartridge is facilitated, as it avoids the need for separate means for transporting and heating the aerosol-forming liquid. As used herein, the term “susceptor arrangement” refers to a component comprising at least one susceptor material having the ability to convert electromagnetic energy into heat when subjected to an alternating magnetic field. This may be the result of at least one of hysteresis loss or eddy current induced within the susceptor material, depending on the electrical properties and magnetism of the susceptor material. Hysteresis loss occurs in ferromagnetic or ferrimagnetic susceptor materials due to magnetic domains in the material being switched under the influence of an alternating electromagnetic field. Eddy currents are induced in conductive susceptor materials. In the case of conductive ferromagnetic or ferrimagnetic susceptor materials, heat is generated by both eddy currents and hysteresis losses. 【0067】 In general, liquid transport susceptor arrangements can have any shape and configuration suitable for transporting aerosol-forming liquid from a storage chamber to a vaporization chamber. In particular, liquid transport susceptor arrangements may include wick elements. The wick elements may consist of stranded wires with sufficient porosity, ropes of stranded material, mesh, mesh tubes, several concentric mesh tubes, cloth, sheets of material, or foam (or other porous solids), rolls of fine metal mesh, or metal foil, any other arrangement of fibers or mesh, or any other shape appropriately sized and configured to perform the wicking action described herein. 【0068】 In particular, the liquid transport susceptor configuration may include a filament bundle containing multiple filaments. The filament bundle is preferably a non-stranded filament bundle. In a non-stranded filament bundle, the filaments of the bundle extend adjacent to each other, preferably along the entire length of the filament bundle, without intersecting each other. Similarly, the filament bundle may include a stranded portion where the filaments of the bundle are stranded. The stranded portion can enhance the mechanical stability of the filament bundle. Since filaments inherently provide capillary action, using filaments to transport liquids is particularly advantageous. Furthermore, in a filament bundle, capillary action is further enhanced due to the narrow spaces formed between multiple filaments when bundled. This is especially true for parallel arrangements of filaments where the capillary action is constant along the parallel arrangement because the narrow spaces between the filaments do not change along the parallel arrangement. 【0069】 As an example, a filament bundle may include a parallel bundle section along at least a portion of its length extension, where multiple filaments can be arranged parallel to each other. The parallel bundle section may be located at one end of the filament bundle or between both ends of the filament bundle. Alternatively, the parallel bundle section may extend along the entire length dimension of the filament bundle. 【0070】 In another embodiment, the filament bundle may include a first immersion section, a second immersion section, and an intermediate section between the first and second immersion sections. Multiple filaments may be arranged parallel to each other, at least along the intermediate section. With respect to a particular configuration of an article having a storage zone and a vaporization zone, each of the first and second immersion sections may be at least partially located within the storage chamber, and the intermediate section may be located within the vaporization chamber. In particular, the filament bundle may be substantially U-shaped, C-shaped, or V-shaped, and each of the first and second immersion sections may each form at least partially U-shaped, C-shaped, or V-shaped arms, and the intermediate section may each form a U-shaped, C-shaped, or V-shaped base. In other words, the arms of the U-shaped, C-shaped, or V-shaped filament bundle may be at least partially disposed within the storage chamber, and the base of the U-shaped, C-shaped, or V-shaped filament bundle may be disposed within the vaporization chamber. 【0071】 Furthermore, the filament bundle may be a linear filament bundle, that is, a substantially straight, uncurved or unbent filament bundle, and one end of the filament bundle may be disposed in the vaporization chamber, and the other end of the filament bundle may be disposed in the storage chamber. 【0072】 The liquid transport susceptor configuration may include at least a first susceptor material. In addition, the liquid transport susceptor configuration may include a second susceptor material. For example, the liquid transport susceptor configuration may include a plurality of first filaments containing or made from the first susceptor material, and a plurality of second filaments containing or made from the second susceptor material. 【0073】 The first susceptor material can be optimized for heat loss and therefore heating efficiency, while the second susceptor material can be used as a temperature marker. For this reason, the second susceptor material preferably includes either a ferrimagnetic or ferromagnetic material. In particular, the second susceptor material may be selected to have a Curie temperature corresponding to a predetermined heating temperature. At that Curie temperature, the magnetism of the second susceptor material changes from ferromagnetic or ferrimagnetic to paramagnetic, accompanied by a transient change in its electrical resistance. Therefore, by monitoring the corresponding change in the current absorbed by the induction source, the change can be detected when the second susceptor material reaches its Curie temperature and, therefore, when it reaches a predetermined heating temperature. 【0074】 The cartridge is preferably substantially cylindrical in shape. The cartridge may have a circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal outer cross-section. 【0075】 The cartridge may have a length extension ranging from 20 mm to 90 mm, particularly from 30 mm to 40 mm, for example, 38 mm. Similarly, the cartridge may have a diameter ranging from 4 mm to 12 mm, particularly from 5 mm to 10 mm, for example, 7.5 mm. 【0076】 The storage chamber may have an extension section with a length of 10 mm to 60 mm, particularly in the range of 20 mm to 40 mm, for example, 25 mm. 【0077】 The vaporization chamber may have an extension in the range of 5 mm to 50 mm, particularly 10 mm to 30 mm, for example, 12 mm, 13 mm, or 15 mm in length. 【0078】 The storage chamber may have a volume ranging from 100 cubic millimeters to 6,000 cubic millimeters, particularly from 400 cubic millimeters to 1,000 cubic millimeters. 【0079】 The vaporization chamber may have a volume ranging from 100 cubic millimeters to 6,000 cubic millimeters, and particularly from 400 cubic millimeters to 1,000 cubic millimeters. 【0080】 The storage chamber may be filled with at least one liquid aerosol-forming substrate, i.e., an aerosol-forming liquid. Alternatively, the storage chamber may be empty. In this configuration, the cartridge may be considered a blank cartridge for the manufacture of an aerosol-generating article, which may be filled with a liquid aerosol-forming substrate and assembled with other components, such as a mouthpiece, to produce the final article. The storage chamber may be configured to be refillable, for example, through a filling hole in the proximal end cap or septum, as detailed above. 【0081】 As used herein, the term “aerosol-forming liquid” refers to a liquid having the ability to release volatile compounds that can form aerosols upon heating. The aerosol-forming liquid is intended to be heated. The aerosol-forming liquid may comprise both solid aerosol-forming materials or components and liquid aerosol-forming materials or components. The aerosol-forming liquid may comprise tobacco-containing materials that contain volatile tobacco-flavoring compounds released from the liquid upon heating. Alternatively or additionally, the aerosol-forming liquid may comprise non-tobacco materials. The aerosol-forming liquid may further comprise aerosol-forming bodies. Suitable examples of aerosol-forming bodies are glycerin and propylene glycol. The aerosol-forming liquid may also comprise other additives and components (such as nicotine or flavorings). In particular, the aerosol-forming liquid may comprise water, solvents, ethanol, plant extracts, and natural or artificial flavors. The aerosol-forming liquid may be an aqueous aerosol-forming liquid or an oil-based aerosol-forming liquid. 【0082】 The present invention relates to a stick-shaped aerosol generating article for use with an induction heating aerosol generator. The article comprises a cartridge according to the present invention and described herein, and a vaporization chamber is disposed at the distal end portion of the article. 【0083】 As used herein, the term “aerosol generating article” refers to consumables used in induction heating aerosol generators, particularly consumables that are disposed of after a single use. Alternatively, the article may be configured for multiple uses. For this purpose, the storage chamber of the article's cartridge may be configured to be refillable, as detailed above. In particular, the article may be configured to be inserted into an induction heating aerosol generator. The aerosol generating article preferably contains at least one liquid stored in the storage chamber of the cartridge, which is intended to be heated rather than burned and, when heated, releases volatile compounds that can form aerosols. 【0084】 The article may be provided with a mouthpiece at its proximal end. That is, the mouthpiece is preferably located proximal to the cartridge. As used herein, the term “mouthpiece” refers to a portion of the article that can be placed in the user’s mouth for direct inhalation of an aerosol from the article. The mouthpiece is preferably located adjacent to the storage chamber, and more particularly adjacent to the proximal end wall member of the storage chamber. In particular, the mouthpiece may be in contact with the storage chamber, and more particularly adjacent to the proximal end wall member of the storage chamber. 【0085】 The mouthpiece may be in fluid communication with the vaporization chamber via a vapor transport conduit. The vapor transport conduit preferably opens directly into the fluid passage through the mouthpiece. Therefore, the mouthpiece may include a vapor inlet at its distal end and a vapor outlet at its proximal end for releasing the vaporized liquid from the article. The fluid passage through the mouthpiece extends from the vapor inlet to the vapor outlet. 【0086】 The mouthpiece may include at least one of an acetate filter plug, a hollow acetate tube, a plastic tube, and an aerosol cooling element. The filter may be used to filter out undesirable components of the aerosol. The mouthpiece may also include additional materials, such as flavoring materials added to the aerosol. The hollow acetate tube or plastic tube may include a central air passage. The aerosol cooling element may allow the aerosol that escapes from the vapor transport conduit of the cartridge to be cooled. The aerosol cooling element may be an element having a large surface area and low draw resistance (e.g., 15 mmWG to 20 mmWG). 【0087】 The mouthpiece may have an extension of length of 3 mm to 15 mm, particularly in the range of 5 mm to 10 mm, for example, 7 mm. 【0088】 Furthermore, as described above, the article may further comprise a first wrapper wound circumferentially around the vaporization chamber and storage chamber, and preferably, if present, around at least the distal portion of the mouthpiece. Advantageously, the wrapper may function to hold the mouthpiece and cartridge together. This results in an article having a stick-like outer shape similar to or equal to an already intended article containing a solid substrate, and therefore suitable for use with an already intended aerosol generator. In particular, the wrapper may help to impart a visual and tactile similarity to a conventional cigarette to the article. For the same purpose, the article may further comprise a second wrapper wound circumferentially around the mouthpiece, and preferably above the first wrapper, around the proximal end portion of the cartridge. The second wrapper may further enhance the visual and tactile similarity to a conventional cigarette. The first wrapper, and the second wrapper, if present, may be paper wrappers. The first wrapper may be wrapped around the mouthpiece and preferably around the proximal end portion of the cartridge, and then the first wrapper may be wrapped over the second wrapper around the vaporization chamber and storage chamber and at least around the distal portion of the mouthpiece. The first and second wrappers may be wrapped around the mouthpiece and cartridge such that the free ends of each wrapper overlap each other. Each of the first and second wrappers may contain an adhesive to bond the free ends of each wrapper together. 【0089】 The article is preferably substantially cylindrical in shape. The article sleeve may have a circular, elliptical, oblong, triangular, rectangular, quadrilateral, hexagonal, or polygonal outer cross-section. 【0090】 The distal end wall member of the vaporization chamber, particularly the distal end cap of the cartridge (if present), can define the most distal end of the article. 【0091】 The article may have an extension in the range of 23 mm to 65 mm, particularly 35 mm to 50 mm, for example, 45 mm in length. 【0092】 Further features and advantages of the aerosol generating article according to the present invention have already been described with respect to the cartridge according to the present invention and apply equally. 【0093】 According to the present invention, an aerosol generating system is also provided, comprising an aerosol generating article as described herein. 【0094】 As used herein, the term “aerosol generator” refers to an electrically operated device having the ability to interact with at least one aerosol-generating article containing at least one aerosol-forming liquid to generate an aerosol by inductively heating the aerosol-forming liquid in a vaporization chamber via the susceptor arrangement of the article. The aerosol generator is preferably a smoke extraction device for generating an aerosol that can be directly inhaled by a user through the user’s mouth. Specifically, the aerosol generator is a handheld aerosol generator. 【0095】 The apparatus may include a receiving cavity for removably receiving at least a portion of an aerosol-generating article, particularly at least a portion of the article's vaporization chamber. 【0096】 The aerosol generator includes an induction heating arrangement configured and positioned to generate an alternating magnetic field within a receiving cavity in order to induce heating of the aerosol-forming liquid within the aerosol-generating article when the article is received into the aerosol generator. 【0097】 To generate an alternating magnetic field, an induction heating aerosol generator, particularly an induction heating arrangement, may include at least one induction coil surrounding at least a portion of a liquid transport susceptor arrangement located within a vaporization chamber when an article is received into the cavity of the device. In particular, the induction coil may exclusively surround a portion of the liquid transport susceptor arrangement located within a vaporization chamber when an article is received into the cavity of the device. The induction coil is preferably arranged around the receiving cavity, particularly around a portion of the receiving cavity where the vaporization chamber is located, and more particularly around a portion of the receiving cavity where a portion of the vaporization chamber, including a portion of the liquid transport susceptor arrangement, is located when an article is received into the cavity of the device. The at least one induction coil may be a helical coil or a flat planar coil, specifically a pancake coil or a curved planar coil. 【0098】 The induction heating arrangement may include an alternating current (AC) generator. The AC generator may be powered by the power supply of the aerosol generator. The AC generator is operably connected to at least one induction coil. Specifically, at least one induction coil may be an integral part of the AC generator. The AC generator is configured to generate a high-frequency oscillating current that passes through at least one induction coil to generate an alternating magnetic field. The AC current may be supplied continuously to at least one induction coil after the system is started, or intermittently (for example, with each smoke extraction). 【0099】 The induction heating arrangement includes a DC / AC converter with an LC network, which preferably comprises a series connection of a capacitor and an inductor. The DC / AC converter may be connected to a DC power supply. 【0100】 The induction heating arrangement is preferably configured to generate a high-frequency magnetic field. As referred to herein, the high-frequency magnetic field may be in the range of 500 kHz to 30 MHz, specifically 5 MHz to 15 MHz, preferably 5 MHz to 10 MHz. 【0101】 The aerosol generator may further include a controller configured to control the operation of the heating process, preferably in a closed-loop configuration, in order to control the heating of the aerosol-forming liquid to a predetermined operating temperature. The operating temperature used to heat the aerosol-forming liquid may be in the range of 100°C to 300°C, particularly 150°C to 250°C, for example, 230°C. 【0102】 The controller may be the overall controller of the aerosol generator, or part of the overall controller of the aerosol generator. The controller may comprise a microprocessor, such as a programmable microprocessor, a microcontroller, or an application-specific integrated circuit chip (ASIC), or other electronic circuitry capable of providing control. The controller may also include further electronic components, such as at least one DC / AC inverter and / or a power amplifier, such as a Class C power amplifier, or a Class D power amplifier, or a Class E power amplifier. Specifically, the induction source may be part of the controller. 【0103】 The aerosol generator may include a DC power supply configured to provide a DC supply voltage and DC supply current to a power source, specifically an induction source. The power supply is preferably a battery, such as a lithium iron phosphate battery. The power supply may be rechargeable. The power supply may have a capacity that allows for the storage of sufficient energy for one or more user experiences. For example, the power supply may have a capacity that allows for continuous aerosol generation for about six minutes, or a time period that is a multiple of six minutes. In another embodiment, the power supply may have a capacity that allows for a predetermined number of smoke inhalations or discontinuous startup of the induction source. 【0104】 The aerosol generator may further include a flux concentrator disposed around at least a portion of the induction coil and configured to distort the alternating magnetic field of the induction coil toward the receiving cavity. Thus, when an article is received into the receiving cavity, the alternating magnetic field is distorted toward the susceptor arrangement. The flux concentrator preferably comprises a flux concentrator foil, specifically a multilayer flux concentrator foil. 【0105】 Further features and advantages of the aerosol generating system according to the present invention have already been described above with respect to the cartridge and aerosol generating article according to the present invention and apply equally. 【0106】 Generally, as used herein, a cartridge, aerosol generating article, or section or component of an aerosol generating device that is closer to the user's mouth during system use is indicated with the prefix "proximal". A section located further away is indicated with the prefix "distal". 【0107】 The present invention is defined in the claims. However, a non-exclusive list of non-limiting embodiments is provided below. One or more features of these embodiments may be combined with any one or more features of other embodiments, forms, or aspects described herein. 【0108】 Example 1: A cartridge for a stick-shaped aerosol generating article for use with an induction heating aerosol generator, wherein the cartridge is A vaporization chamber located at the distal end of the cartridge is used to vaporize the aerosol-forming liquid contained within, A storage chamber for storing aerosol-forming liquid, located proximal to the vaporization chamber, A liquid transport susceptor is configured and arranged to transport the aerosol-forming liquid from the storage chamber into the vaporization chamber and vaporize the aerosol-forming liquid in the vaporization chamber, and is inductively heated when used with the apparatus. A vapor transport conduit provides fluid communication for the vaporized aerosol-forming liquid from the vaporization chamber to the proximal region of the storage chamber, A cartridge comprising a proximal end cap forming at least a proximal end wall member of a storage chamber, the proximal end cap having a through hole through which the proximal end portion of a steam transport conduit passes, is supported therein, or terminates integrally therein. Example 2: The cartridge according to Example 1, wherein the proximal end cap is not integrated with any other wall member of the storage chamber. Example 3: The cartridge according to either Example 1 or 2, wherein the proximal end cap is attached to the cartridge by press fitting, snap fitting, welding, or adhesive bonding. Example 4: A cartridge according to any one of Examples 1 to 3, wherein the proximal end cap is not integrated with any of the wall members of the vaporization chamber. Example 5: The cartridge according to any one of Examples 1 to 4, wherein the proximal end cap includes a distal recess that forms the distal portion of a through hole in which the proximal end portion of a steam transport conduit is supported. Example 6: The cartridge according to Example 5, wherein the inner cross-section of the distal recess is larger than the inner cross-section of the proximal portion of the through hole other than the distal portion. Example 7: The cartridge according to Example 6, wherein the inner cross-section of the proximal portion of the through-hole corresponds to the inner cross-section of the steam transport conduit. Example 8: A cartridge according to any one of Examples 1 to 7, wherein the proximal end cap includes a distal insertion socket that protrudes into the storage chamber, and the distal insertion socket forms the distal portion of a through hole in which the proximal end portion of a steam transport conduit is supported. Example 9: The cartridge according to Example 8, wherein the inner cross-section of the distal insertion socket is larger than the inner cross-section of the proximal portion of the through hole other than the distal portion. Example 10: The cartridge according to Example 9, wherein the inner cross-section of the proximal portion of the through-hole corresponds to the inner cross-section of the steam transport conduit. Example 11: A cartridge according to any one of Examples 1 to 10, wherein the proximal end cap is made of plastic or silicone. Example 12: A cartridge according to any one of Examples 1 to 11, wherein the proximal end cap includes at least one filling hole for filling the storage chamber with an aerosol-forming liquid. Example 13: The cartridge according to Example 12, comprising a proximal plug member that seals at least one filling hole of the proximal end cap. Example 14: The cartridge according to Example 13, wherein the proximal end cap includes a proximal recess in which a proximal plug member is received. Example 15: The cartridge according to any one of Examples 12 to 13, wherein the proximal plug member includes a through hole that matches the through hole of the proximal end cap. Example 16: The cartridge according to Example 15, wherein the cross-section of the through-hole of the proximal plug member corresponds to the inner cross-section of the steam transport conduit. Example 17: A cartridge according to any one of Examples 1 to 16, wherein the proximal end cap is plug-shaped. Example 18: The cartridge according to Embodiment 17, comprising a plug body in which a plug-shaped proximal end cap is inserted into the circumferential outer wall member of the storage chamber. Example 19: The cartridge according to Example 18, wherein the plug body is substantially cylindrical or frustoconical in shape. Example 20: The cartridge according to any one of Examples 18 to 19, wherein the plug body comprises a circumferential collar that provides a sealing fit of the proximal end cap to the circumferential outer wall member of the storage chamber within the cartridge. Example 21: A cartridge according to any one of Examples 17 to 20, wherein the plug-shaped proximal end cap is equipped with a cover plate. Example 22: A cartridge according to any one of Examples 17 to 21, wherein the plug-shaped proximal end cap, particularly the cover plate, includes a protruding collar that abuts against the proximal front end of the circumferential outer wall member of the storage chamber. Example 23: The cartridge according to any one of Examples 17 to 22, further comprising an insertion portion in which a plug-shaped proximal end cap is at least partially inserted into the circumferential outer wall member of the storage chamber. Example 24: The cartridge according to Example 23, wherein the insertion portion includes an insertion ring, or an insertion tube, or an insertion cylinder, or a hollow insertion cylinder, or a plurality of insertion ring segments, or a plurality of insertion pins, or a plurality of insertion fins. Example 25: A cartridge according to any one of Examples 1 to 24, wherein the proximal end cap is cup-shaped. Example 26: The cartridge according to Example 25, wherein the cup-shaped proximal end cap includes a bottom portion that forms the proximal end wall member of the storage chamber and a sleeve portion that forms the circumferential outer wall member of the storage chamber. Example 27: The cartridge according to any one of Examples 1 to 26, wherein the proximal end cap includes a part of an integrated body comprising a proximal end portion and at least one of an outer sleeve portion and an inner tube portion, the outer sleeve portion forming a circumferential outer wall member of the storage chamber, the proximal end portion corresponding to the proximal end cap forming the proximal end wall member of the storage chamber, and the inner tube portion forming a steam transport conduit. Example 28: The cartridge according to Example 27, wherein the outer sleeve portion may further form a circumferential outer wall member (or a portion thereof) of the vaporization chamber. Example 29: A stick-shaped aerosol generating article for use with an induction heating aerosol generator, wherein the article comprises a cartridge described in any one of Examples 1 to 28, and a vaporization chamber is disposed at the distal end of the article. Example 30: The article according to Example 29, further comprising a mouthpiece at the proximal end portion of the article. Example 31: An aerosol generating system comprising an aerosol generating article described in any one of Examples 29 to 30, and an induction heating aerosol generating device for use with the article. Example 32: The aerosol generating system according to Example 31, wherein the aerosol generating device includes a receiving cavity for removably receiving at least a portion of an aerosol generating article, in particular at least a portion of the vaporization chamber of the article. Example 33: The aerosol generating system according to Example 32, wherein the aerosol generating device comprises an induction coil that surrounds at least a portion of the liquid transport susceptor arrangement located within the vaporization chamber when an article is received into the cavity of the device. 【0109】 Here, we will further describe the embodiments with reference to the figures. 【0110】 Figure 1 schematically shows the general structure and components of the stick-shaped aerosol generating article 1 according to the present invention in an exploded view. As will be described in more detail below with respect to Figure 3, the aerosol generating article 1 is configured to be used together with an induction heating aerosol generator to vaporize the aerosol-forming liquid 19 provided by the aerosol generating article 1. 【0111】 The aerosol generating article 1 shown in Figure 1 comprises two main components: a cylindrical cartridge 10 for storing and vaporizing an aerosol-forming liquid 19, and a cylindrical mouthpiece 90 that the user can inhale to create an airflow (indicated by arrow 21) through the article 1, in which volatile compounds released from the heated aerosol-forming liquid 19 are entrained and condensed at the proximal end 92 of the mouthpiece 90, forming an aerosol that exits the article 1. 【0112】 According to the present invention, the cartridge 10 comprises a vaporization chamber 11 at the distal end of the cartridge 10 for vaporizing an aerosol-forming liquid therein. The vaporization chamber 11 includes two air intakes 13 that allow air to enter the article when the user inhales smoke through the mouthpiece 90. The cartridge 10 further comprises a storage chamber 12 proximal to the vaporization chamber 11 for storing the aerosol-forming liquid 19. Furthermore, the cartridge 10 comprises a liquid transport susceptor arrangement 40 configured and disposed to transport the aerosol-forming liquid 19 from the storage chamber 12 into the vaporization chamber 11. In addition, the liquid transport susceptor arrangement 40 is configured and disposed to be inductively heated when exposed to an alternating magnetic field when used with a corresponding aerosol generator to vaporize the aerosol-forming liquid 19 in the vaporization chamber 11. Furthermore, the cartridge 10 includes a vapor transport conduit 20 that provides fluid communication for air and vaporized aerosol-forming liquid from the vaporization chamber 11 to the proximal region of the storage chamber 13, i.e., to the mouthpiece 90 disposed adjacent to the proximal end wall member 14 of the storage chamber 12. As can be seen further from Figure 1, the mouthpiece 90 of this embodiment includes a hollow acetate tube that provides a central fluid passage 91 through the mouthpiece 90, into which the vapor transport conduit 20 opens directly, allowing aerosols formed in the article to escape from the article through the vapor outlet of the fluid passage 91 at the proximal end 92 of the mouthpiece 90. 【0113】 The cartridge 10 and the mouthpiece 90 are separate parts that may be manufactured separately, particularly in different locations, and then assembled together to form the aerosol generating article 1 according to the present invention. For assembly, a cylindrical mouthpiece 90 having substantially the same cross-sectional shape as the cylindrical cartridge 10 may be positioned proximal to the storage chamber 12, adjacent to the cartridge 10, so as to abut against the proximal end wall member 14 of the storage chamber 12. Then, as shown in Figure 1, a first wrapper 95 may be wound around at least the axial portion of the cartridge 10 and the mouthpiece 90 to hold the mouthpiece 90 and cartridge 10 together. Also as shown in Figure 1, a second wrapper 96 may be wound circumferentially around the mouthpiece 90 and preferably around the proximal end portion of the cartridge 10, above the first wrapper 95. The first wrapper 95 and the second wrapper 96 may be wound around the mouthpiece 90 and cartridge 10 such that the free ends of the respective wrappers 95, 96 overlap each other. Each of the first and second wrappers may contain an adhesive that bonds the free ends of each wrapper together. This process ultimately yields an aerosol-generating article 1 having a stick-like outer shape similar to or equal to an already intended article containing a solid substrate, as described, for example, in WO2015 / 177294A1. 【0114】 A first exemplary embodiment of such article 101 is shown in Figure 2. Features identical or similar to those of the general article design schematically shown in Figure 1 are indicated by the same reference numerals, but incremented by 100. Further details of article 101, in particular the cartridge 110 and its components, are described below in detail with respect to Figures 4-7. According to the general article design, article 101 comprises a cylindrical cartridge 110 arranged axially adjacent to one another and wrapped by a first paper wrapper 195 and a second paper wrapper 196, and a cylindrical mouthpiece 190 formed of a hollow acetate tube. The cartridge 110 comprises a cylindrical cartridge sleeve 170 that integrally forms the circumferential outer wall member 117 of the vaporization chamber 111 and the circumferential outer wall member 116 of the storage chamber 112. The cartridge 110 further comprises a proximal end cap 130 that forms the proximal end wall member 114 of the storage chamber 112. Similarly, the cartridge 110 includes a distal end cap 150 that forms the distal end wall member 115 of the vaporization chamber 111. Both the proximal end cap 130 and the distal end cap 150 are fitted by press into the proximal and distal openings of the cartridge sleeve 170, respectively. The cartridge further includes a disc-shaped septum 160 that forms a common wall member of the vaporization chamber 111 and the storage chamber 112, separating the interior of the vaporization chamber 111 from the interior of the storage chamber 112. Similar to the proximal end cap 130 and the distal end cap 150, the disc-shaped septum 160 is fitted by press between its ends within the cartridge sleeve 170 such that the interior of the cartridge sleeve 170 is divided in a ratio of approximately 1:3. 【0115】 To transport the aerosol-forming liquid 119 stored in the storage chamber 112 into the vaporization chamber 111, the cartridge 110 according to this embodiment includes a liquid transport susceptor arrangement 140 formed by a U-shaped filament bundle 141 containing a plurality of filaments arranged parallel to each other. Because the filaments are arranged parallel to each other in the bundle, a narrow space is formed between the plurality of filaments, thereby providing capillary action and enabling the transport of the liquid along the length extension of the filaments. At least a portion of the filaments is made of an induction-heatable material, such as stainless steel. Thus, the filament bundle 141 can perform two functions: transporting and heating the aerosol-forming liquid. As can be seen in Figure 2, the U-shaped filament bundle 141 includes a base and two arms, the arms passing through their respective feedthroughs 161 of the septum 160. The distal portions of each arm are disposed in the storage chamber 112 for immersion of the aerosol-forming liquid 119. Thus, the distal portions of the two arms may be shown as the immersion section 142. In contrast, the base and the proximal portions of each arm are arranged within the vaporization chamber to form a vaporization section 143 that can be inductively heated when exposed to an alternating magnetic field. In this way, the aerosol-forming liquid 119, transported from the storage chamber 112 to the vaporization section 143 via the immersion section 142, is vaporized within the vaporization chamber 111. To allow air to enter the article 101 for aerosol generation, the vaporization chamber 111 includes two air intakes 113 at the distal end of the article 101. To transport the air and vaporized liquid proximal to the mouthpiece 190, the cartridge 110 according to this embodiment includes an inner tube 121 that forms a transport conduit 120 providing fluid communication between the vaporization chamber 111 and the central passage 191 of the mouthpiece 190. Further details of the proximal end cap 130, distal end cap 150, inner tube 121, and septum 160 are described below with reference to Figures 4-7. 【0116】 Due to its stick-like shape and the arrangement of the vaporization chamber 111 at the distal end of the cylindrical article 101, article 101 is adapted for use with the induction heating aerosol generator 3 already intended for solid substrate consumables, as described with respect to Figure 3. For this reason, the device can generally be used with different types of articles to generate aerosols from different types of aerosol-forming substrates, particularly from both solid and liquid substrates. 【0117】 Figure 3 schematically shows an aerosol generating system 2 according to an exemplary embodiment of the present invention. System 2 comprises an aerosol generating article 101 shown in Figure 2, and an induction heating aerosol generating device 3 having the capability to interact with the article 101 to generate an aerosol. For this purpose, the aerosol generating device 3 includes a receiving cavity 4 formed in the device housing at the proximal end of the device 3. The receiving cavity 4 is configured to removably receive at least a portion of the aerosol generating article 101. In particular, the aerosol generating device 3 is configured to induction heat the heating section 143 of the filament bundle 141 to a temperature sufficient to vaporize the aerosol-forming liquid that has been transported from the storage chamber 112 to the heating section 143 via the immersion section 142. For this purpose, the device 3 includes an induction heating arrangement including an induction coil 5. In this embodiment, the induction coil 5 is a single helical coil positioned around the proximal end portion of the receiving cavity 4 such that it surrounds only the heating section 143 of the liquid transport susceptor arrangement 140 when the article 101 is received in the cavity 4. Therefore, when the induction coil 5 is driven with AC current during use of the device 3, the induction coil 5 generates an alternating magnetic field that largely penetrates the heating section 143 within the vaporization chamber 111 of the article 101. In contrast, due to localized heating, the immersion section 142 of the U-shaped filament bundle 141 remains below its vaporization temperature. Thus, boiling of the aerosol-forming liquid 191 in the storage chamber 112 is prevented. Therefore, during operation, the liquid transport susceptor arrangement 140 includes a temperature profile that shows a temperature rise from below the vaporization temperature of the aerosol-forming liquid 191 in the immersion section 142 to above the respective vaporization temperatures in the heating section 143. The aerosol generator 3 further comprises a controller 6 for controlling the operation of the entire system 2, in particular for controlling the heating operation. Furthermore, the aerosol generator 3 comprises a power supply 7 that provides power for generating an alternating magnetic field. The power supply 7 is preferably a battery, such as a lithium iron phosphate battery. The power supply 7 may have a capacity that allows for the storage of sufficient energy for one or more user experiences. Both the controller 6 and the power supply 7 are located in the distal part of the aerosol generator 3. 【0118】 In the use of System 2, when the user inhales smoke through the mouthpiece 190, air is drawn into the cavity 4 at the edge of the article insertion opening 8. The airflow further extends toward the distal end of the cavity 4 through a passage formed between the inner surface of the cylindrical cavity 4 and the outer surface of the article 101. At the distal end of the cavity 4, the airflow enters the vaporization chamber 111 through the air intake 113. From there, the airflow further passes through the vapor transport conduit 120 to the mouthpiece 190 and finally exits from the article 101. In the vaporization chamber 111, vaporized aerosol-forming liquid 119 is entrained in the airflow. As the air and vaporized liquid 119 flow further through the vapor transport conduit 120 and the central air passage 191 of the mouthpiece 190, the flow is cooled to form an aerosol that escapes from the article 101 through the mouthpiece 190. 【0119】 Referring to Figures 4-7, further details of the cartridge 110 of article 101 according to Figures 2-3 are described below. Figure 4 is an enlarged view of Figure 2, but does not show the mouthpiece 190 and the first and second wrappers 195 and 196. Similarly, Figure 5 is a perspective view of the cartridge 110 according to Figure 2. Figure 6 shows a front view of the septum 160 seen in the proximal direction, and Figure 7 shows a perspective view of the distal end cap 150. 【0120】 As can be seen from Figures 4 and 5, the inner tube 121 forming the steam transport conduit 120 is a cylindrical tube having a circular inner cross-section and a circular outer cross-section. The inner tube 121 is preferably made of plastic. Because of its cylindrical shape, it can be advantageously manufactured by extrusion molding. As can be seen further from Figures 4 and 5, the inner tube 121 extends coaxially with the cartridge sleeve 170 along the entire axial length extension of the storage chamber 112, from the proximal end cap 130 to the septum 160. Thus, the inner tube 121 also forms an inner wall member of the storage chamber 112. For this reason, the volume of the storage chamber 112 is substantially a hollow cylinder. In particular, the inner tube 121 is non-integrated (separate) with the plug-shaped proximal end cap 130 and the disc-shaped septum 160. As can be seen best from Figure 4, the proximal end cap 130 has a through-hole 135 that is continuous with the fluid communication provided by the steam transport conduit 120. In particular, the proximal end cap 130 includes a distal recess 136 that forms the distal portion of the through-hole 135, in which the proximal end portion of the inner tube 121 is internally supported. The inner cross-section of the distal recess 136 is larger than the inner cross-section of the remaining proximal portion 137 of the through-hole 135. Thus, the distal recess 136 forms a contact portion with the inner tube 121 for fixing its position in the proximal direction. The inner cross-section of the proximal portion 137 of the through-hole 135 corresponds to the inner cross-section of the inner tube 121, so that the airflow passage through the steam transport conduit 120 is smoothly continuous through the proximal portion 137 of the through-hole 135. 【0121】 Similarly, the distal end portion of the inner tube 121 is supported within a through-hole 165 of the septum 160 that connects the steam transport conduit 120 to the vaporization chamber 111. Similar to the proximal end cap 130, the septum 160 includes a proximal recess 166 that forms the proximal portion of the through-hole 165, within which the steam transport conduit is supported at its distal end. The inner cross-section of the proximal recess 166 is larger than the inner cross-section of the remaining distal portion 167 of the through-hole 165 to provide a contact surface with respect to the inner tube 121 in the distal direction. To ensure a smooth continuity of the airflow passage from the vaporization chamber 111 into the steam transport conduit 120, the inner cross-section of the distal portion 167 of the through-hole 165 corresponds to the inner cross-section of the inner tube 121. The fact that both ends of the inner tube 121 are supported within recesses 136 and 166 is particularly advantageous with respect to proper sealing between the steam transport conduit 140 and the end wall members of the storage chamber 112. 【0122】 As already mentioned above, the septum 160 also includes two feedthrough openings 161 through which the U-shaped arms of the filament bundle 141 pass. The cross-sectional dimensions of the feedthrough openings 161 are selected so that the liquid transport susceptor arrangement 140 is fixedly held by the septum 160. Advantageously, the liquid transport susceptor arrangement 140 is fixed to the septum 160 before the cartridge 110 is assembled to facilitate assembly. As shown in Figure 6, the septum further includes two filling holes 169 arranged transversely on opposing sides of the through-hole 165 for filling the storage chamber 112 with aerosol-forming liquid 191 via the vaporization chamber 111 before the distal end cap 150 is attached to the distal end of the cartridge sleeve 170. 【0123】 Furthermore, the septum 160 includes a circumferential collar 168 having a cross-sectional shape corresponding to the inner cross-section of the cartridge sleeve 170. Thus, the collar 168 functions to securely mount the septum 160 within the cartridge 110 by press fitting. In addition, the collar 168 provides a sealed fit of the septum 160 to the inner surface of the cartridge sleeve 170, thus preventing leakage of the aerosol-forming liquid from the storage chamber 112 into the vaporization chamber. 【0124】 The plug body of the proximal end cap 130, which is fully inserted into the proximal end of the cartridge sleeve 170, also has a cross-sectional shape that corresponds to the inner cross-section of the cartridge sleeve 170. Therefore, the proximal end cap 130 is also sealed and fixedly attached inside the cartridge sleeve 170 by press fitting. 【0125】 Both the proximal end cap 130 and the septum are preferably made of silicone. Silicone has suitable sealing properties and is inexpensive, which is particularly important in relation to the fact that the cartridge 110 is preferably used in an aerosol generating article 101 configured for single use only. Also, silicone is not induction heated, which prevents the energy provided by the alternating magnetic field from being unnecessarily dissipated within the septum 160 and proximal end cap 130. 【0126】 As best seen in Figure 7 in combination with Figures 4 and 5, the plug-shaped distal end cap 150 includes a cover plate 151 and an insertion portion 152. The cover plate 151 extends radially outward beyond the insertion portion 152 and the inner cross-section of the cartridge sleeve 170 so as to abut against the distal front end of the cartridge sleeve 170. The insertion portion 152 is inserted into the distal end portion of the cartridge sleeve 170, which forms the circumferential outer wall member 117 of the vaporization chamber 111. In this embodiment, the insertion portion 152 includes an insertion ring 153 and two support legs 154 extending along the inner surface of the circumferential outer wall member 117 of the vaporization chamber 111. The length of the support legs 154 is selected so that when the distal end plug 150 is installed inside the cartridge 110, the legs 154 abut against the septum 160 and the cover plate 151 abuts against the distal front end of the cartridge sleeve 170. Therefore, the distal end cap 150 is fixed in a fixed position in the proximal direction. Conversely, the septum 160 is fixed in the distal direction, and the proximal end cap is also fixed in the proximal direction via the inner tube 121. 【0127】 In addition, the plug-shaped distal end cap 150 includes a plug member 159 at the proximal end of each support leg 154 for sealing the filling hole 169 in the septum 160 when the distal end plug 150 is installed inside the cartridge 110. Advantageously, this configuration allows sealing the filling hole 169 and closing the distal end of the vaporization chamber 111 to be performed in a single step by installing the plug-shaped distal end cap 150. 【0128】 According to this embodiment, the air intake port 113 of the vaporization chamber 111 is formed within the distal end cap 150. As is best seen in Figure 7, each air intake port 113 includes a ventilation groove 157 formed on the outer surface of the distal end cap 150 facing the cartridge sleeve 117, i.e., the outer surface of the insertion ring 153 and the outer portion of the cover plate 151. 【0129】 To provide good thermal stability for article 101, the distal end cap 150 and cartridge 117 are preferably made of PEEK. Furthermore, PEEK is not induction heatable, thus preventing the user from being burned when touching article 101 immediately after the heating process. 【0130】 Figures 8-11 show a second embodiment of the cartridge 210 according to the present invention, which can be used as an alternative to the aerosol generating article shown in Figure 2. The general setup of this cartridge is similar to the setup of the cartridge shown in Figures 4-7. Thus, identical or similar features are indicated by the same reference numerals, but incremented by 100. In contrast to the first embodiment shown in Figures 4-7, the cartridge 210 according to Figures 8-11 comprises a cylindrical inner tube 221 having elliptical inner and outer cross-sections. Advantageously, the elliptical cross-section provides more free space within the storage chamber for arranging the immersion section 242 of the filament bundle 241 on both sides of the long axis of the elliptical inner tube 221. Thus, the through-hole 235 in the proximal end cap 230 and the through-hole 265 in the septum 260 also have elliptical cross-sections corresponding to the dimensions and orientation of the elliptical inner and outer cross-sections of the inner tube 221. 【0131】 Furthermore, in contrast to the first embodiment shown in Figures 4-7, the septum 260 of the cartridge 210 shown in Figures 8-11 includes a proximal insertion socket 266 that protrudes into the storage chamber 212. Details of the septum 260, and in particular the proximal insertion socket 266, are shown in Figure 10. The proximal insertion socket 260 forms the proximal portion of the through-hole 265, into which the distal end portion of the inner tube 221 is supported. Thus, the proximal insertion socket 266 can be considered a projection extending into the storage chamber 212, including a recess that forms the proximal portion of the through-hole 265. The elliptical inner cross-section of the proximal insertion socket 266 is larger than the elliptical inner cross-section of the remaining distal portion 267 of the through-hole 265, and therefore provides a contact portion with respect to the distal end portion of the inner tube 221 in the distal direction. To provide a substantially smooth airflow passage through the cartridge 210, the elliptical inner cross-section of the distal portion 267 of the through-hole 265 corresponds to the elliptical inner cross-section of the inner tube 221. 【0132】 As can be seen further from Figure 10, the septum 260 of the cartridge 210 according to the second embodiment does not include a filling hole, in contrast to the first embodiment shown in Figures 4-7. Instead, as shown in Figure 11, the proximal end cap 230 includes two filling holes 239 arranged transversely on the opposing sides of an elliptical through-hole 235 for filling the storage chamber 212 with the aerosol-forming liquid 291 through the proximal end of the cartridge 210. To seal the filling holes 239 when filling the storage chamber 212, the cartridge 210 includes a proximal plug member 233, the details of which are also shown in Figure 11. To have a substantially flat proximal surface at the proximal end of the cartridge 210, the proximal end cap 230 includes a proximal recess 231 into which the proximal plug member 233 is received. One or more filling holes may be arranged adjacent to the through-hole 235 of the proximal end cap. For example, the proximal end cap may include two filling holes arranged transversely on opposite sides of the through hole. The proximal plug member 233 includes a disc 232 having a projection 238 that tightly fits into the filling hole 239 of the proximal end cap 230. To allow the aerosol to escape freely proximal to the cartridge 210, the proximal plug member 233 may include a through hole 234 in the disc 232 that matches the through hole 235 of the proximal end cap 230. The cross section of the through hole 234 of the proximal plug member preferably corresponds to the inner cross section of the steam transport conduit 220 in order to provide a smooth airflow passage. 【0133】 Figures 12-13 show a third embodiment of the cartridge 310 according to the present invention, which can be used as an alternative to the aerosol generating article shown in Figure 2. The general setup of this cartridge is similar to the setup of the cartridges shown in Figures 4-7. Thus, identical or similar features are indicated by the same reference numerals, but incremented by 200. In contrast to the first embodiment shown in Figures 4-7, the cartridge 310 shown in Figures 12-13 comprises a cup-shaped proximal end cap 330 and a cup-shaped distal end cap 350, rather than a cylindrical cartridge sleeve. The cup-shaped proximal end cap 330 includes a bottom portion 331 that forms the proximal end wall member 314 of the storage chamber 312 and a sleeve portion 332 (cup-shaped side wall) that forms the circumferential outer wall member 315 of the storage chamber 312. Similarly, the cup-shaped distal end cap 350 includes a bottom portion 351 that forms the distal end wall member 315 of the vaporization chamber 311 and a sleeve portion 352 (cup-shaped side wall) that forms the circumferential outer wall member 317 of the vaporization chamber 311. In this configuration, the storage chamber 312 and the vaporization chamber are substantially entirely formed by the proximal end cap 330 and the distal end cap 350, respectively. The missing wall member is formed by a septum 360, which is also used as a joining link to which the proximal end cap 330 and the distal end cap 350 are attached by press fitting. As can be seen in Figure 12, the septum 360 includes a circumferential projection 363 against which the distal surface of the sleeve portion 332 and the proximal surface of the sleeve portion 352 abut. 【0134】 Furthermore, in contrast to the first embodiment shown in Figures 4-7, the cup-shaped proximal end cap 330 of the cartridge 210 shown in Figures 12-13, similar to the septum 260 shown in Figures 8-11, includes a distal insertion socket 336 that protrudes into the storage chamber 312, forming a through hole 335 and completely supporting the proximal end portion of the steam transport conduit 320 inside. 【0135】 Figures 14-16 show a fourth embodiment of the cartridge 410 according to the present invention, which can be used as an alternative to the aerosol generating article shown in Figure 2. The general setup of this cartridge is similar to the setup of the cartridges shown in Figures 4-7. Thus, identical or similar features are indicated by the same reference numerals, but incremented by 300. In contrast to the first embodiment shown in Figures 4-7, the cartridge 410 shown in Figures 14-16 does not have a cartridge sleeve, inner tube, and proximal end cap separated from each other. Instead, the cartridge 410 comprises a single body 480 including a proximal end portion 483, an outer sleeve portion 487, and an inner tube portion 482 coaxially disposed within the outer sleeve portion 487. The outer sleeve portion 487 extends along the entire axial length extension of the storage chamber 412 and the vaporization chamber 411, thus forming the circumferential outer wall member 416 of the storage chamber 412 and the circumferential outer wall member 417 of the vaporization chamber 411. The proximal end portion 483 forms the proximal end wall member 414 of the storage chamber 412, including a through hole 485 into which the proximal end of the inner tube portion 482 opens inward. The inner tube portion 482 forms the steam transport conduit 420 and, at the same time, the inner wall member of the hollow cylindrical storage chamber 412. In this invention, the inner tube portion 482 extends along the entire axial length extension of the storage chamber 412, and further through the through hole 465 of the septum 460, extending into the vaporization chamber 411. Advantageously, such an integrated body 410 facilitates the construction and assembly of the cartridge 410. The proximal end portion may correspond to the proximal end cap described above, which forms the proximal end wall member of the storage chamber. As in other embodiments, the septum 460 is attached to the outer sleeve portion 487 using a collar 468, preferably by press fitting, snap fitting, welding, or adhesive bonding. The integrated body 480 is combined with a distal end cap 450, which is not integrated with the integrated body 480 as detailed above, and is attached to the distal end of the integrated body 480 by press fitting, snap fitting, welding, or adhesive bonding.Both the integrated body 480 and the distal end cap 450 are preferably injection molded using PEEK to prevent the user from being burned when touching the article containing the cartridge 410 immediately after the heating process. 【0136】 Referring to Figure 16, the cartridge 410 further comprises sealing rings 449 for each of the feed-through openings 461 of the septum 460. In this embodiment, the sealing rings 449 are overmolded around those portions of the liquid transport susceptor arrangement 440 that pass through the feed-through openings 461. Advantageously, this provides particularly good sealing and facilitates the assembly of the cartridge 410. Preferably, the filament bundle 441 forming the liquid transport susceptor arrangement 440 is overmolded with the sealing rings 449 before assembling the cartridge 410. 【0137】 For the purposes of this specification and the appended claims, unless otherwise indicated, all numbers representing amounts, quantities, percentages, etc., should be understood in all cases as being modified by the term “approximately.” Furthermore, all ranges include the disclosed maximum and minimum points and any intermediate ranges therewith, which may or may not be specifically listed herein. Thus, in this context, number A is understood as 5 percent of A ± A. In this context, number A may be considered to include a number that falls within the general standard error of the measurement of the characteristic modified by number A. Number A may deviate by the percentages listed above, provided that in some cases, such as those used in the appended claims, the amount by which A deviates does not substantially affect the fundamental and novel characteristics of the claimed invention. Furthermore, all ranges include the disclosed maximum and minimum points and any intermediate ranges therewith, which may or may not be specifically listed herein.

Claims

[Claim 1] A cartridge for a stick-shaped aerosol generating article, wherein the article is to be used together with an induction heating aerosol generating device, and the cartridge is A vaporization chamber located at the distal end of the cartridge for vaporizing the aerosol-forming liquid contained therein, A storage chamber for storing aerosol-forming liquid, located proximal to the vaporization chamber, A liquid transport susceptor is provided, configured and arranged to be inductively heated when used with the apparatus, in order to transport the aerosol-forming liquid from the storage chamber into the vaporization chamber and vaporize the aerosol-forming liquid in the vaporization chamber. A vapor transport conduit provides fluid communication for the vaporized aerosol-forming liquid from the vaporization chamber to the proximal region of the storage chamber, A proximal end cap forming at least a proximal end wall member of the storage chamber, wherein the proximal end cap includes at least one filling hole for filling the storage chamber with an aerosol-forming liquid, and the proximal end cap includes a through hole in which the proximal end portion of the vapor transport conduit is supported, A distal recess that forms the distal portion of the through hole in which the proximal end portion of the steam transport conduit is supported, wherein the inner cross-section of the distal recess is larger than the inner cross-section of the proximal portion of the through hole other than the distal portion, or A cartridge comprising a proximal end cap, which includes a distal insertion socket protruding into the storage chamber, wherein the distal insertion socket forms the distal portion of the through hole in which the proximal end portion of the steam transport conduit is supported, and the inner cross-section of the distal insertion socket is larger than the inner cross-section of the proximal portion of the through hole other than the distal portion. [Claim 2] The cartridge according to claim 1, wherein the proximal end cap is not integrated with any other wall member of the storage chamber. [Claim 3] The cartridge according to claim 1 or 2, wherein the proximal end cap is attached to the cartridge by press fitting, snap fitting, welding, or adhesive bonding. [Claim 4] The cartridge according to any one of claims 1 to 3, wherein the proximal end cap is not integrated with any of the wall members of the vaporization chamber. [Claim 5] The cartridge according to any one of claims 1 to 4, wherein the inner cross-section of the proximal portion of the through hole of the proximal end cap corresponds to the inner cross-section of the steam transport conduit such that the airflow passage through the steam transport conduit is smoothly continuous through the proximal portion of the through hole. [Claim 6] The cartridge according to any one of claims 1 to 4, wherein the inner cross-section of the proximal portion of the through hole may be larger or smaller than the inner cross-section of the steam transport conduit. [Claim 7] The cartridge according to any one of claims 1 to 6, further comprising a proximal plug member for sealing the at least one filling hole of the proximal end cap. [Claim 8] The cartridge according to claim 7, wherein the proximal end cap includes a proximal recess in which the proximal plug member is received. [Claim 9] The cartridge according to claim 7 or 8, wherein the proximal plug member includes a through hole that matches the through hole of the proximal end cap. [Claim 10] The cartridge according to any one of claims 1 to 9, wherein the proximal end cap is plug-shaped. [Claim 11] The cartridge according to claim 1, wherein the proximal end cap is cup-shaped, and the cup-shaped proximal end cap includes a bottom portion that forms the proximal end wall member of the storage chamber and a sleeve portion that forms the circumferential outer wall member of the storage chamber. [Claim 12] The cartridge according to claim 1, wherein the proximal end cap is part of an integrated body including a proximal end portion and an outer sleeve portion, the outer sleeve portion forms a circumferential outer wall member of the storage chamber, and the proximal end portion corresponds to the proximal end cap that forms the proximal end wall member of the storage chamber. [Claim 13] The cartridge according to claim 12, wherein the outer sleeve portion also forms the circumferential outer wall member or at least a portion thereof of the vaporization chamber. [Claim 14] A stick-shaped aerosol generating article for use with an induction heating aerosol generating device, wherein the article comprises a cartridge according to any one of claims 1 to 13 and a mouthpiece located at the proximal end of the article, and the vaporization chamber is disposed at the distal end of the article.

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