The present disclosure relates generally to heat distribution in aerosol or vapor generation systems and devices, in particular to a heater for aerosol or vapor generation devices with removable consumable articles such as capsules or other liquid-containing devices for removable connection to an aerosol or vapor generating device, to precise heat distribution in the removable consumable article and to clamping of the removable consumable article at the time of inserting the removable consumable article on the aerosol or vapor generation system.
BACKGROUNDThe use of aerosol generating systems, also known as e-cigarettes, e-cigs (EC), electronic nicotine delivery systems (ENDS), electronic non-nicotine delivery systems (ENNDS), electronic smoking devices (ESDs), personal vaporizers (PV), inhalation devices, vapes, which can be used as an alternative to conventional smoking articles such as lit-end cigarettes, cigars, and pipes, is becoming increasingly popular and widespread. The most commonly used e-cigarettes are usually battery powered and use a resistance heating element to heat and atomize a liquid containing nicotine and/or flavorants (also known as e-cigarette liquid, e-cig liquids, e-liquid, juice, vapor juice, smoke juice, e-juice, e-fluid, vape oil), to produce a nicotine-containing condensation aerosol (often called vapor) which can be inhaled by a user. The aerosol can be inhaled through a mouthpiece, which, in the case of aerosols formed from e-liquids which contain nicotine and/or flavorants.
In the conventional e-cigarettes described above, the liquid is put into contact with a resistance heating element after flowing through small channels, where it is heated and vaporized. The flowing is realized for example via a wick, a mesh or another type of porous element, which has a plurality of small channels that transport the liquid from a reservoir to the heating element. This heating element together with the porous element, a reservoir that contains the e-liquid, and a mouthpiece are usually arranged within a disposable capsule, cartridge or pod, that is discarded or refilled once the e-liquid has been consumed by the user, and usually removably connects to a main body that includes a rechargeable battery.
Enabling a precise distribution of heat inside the consumable article in order to bring heat to specific parts thereof, for example parts that carry a wicking element to be soaked with e-liquid allows to selectively vaporize substance to be delivered through the air channels. It also improves heating efficiency, e-liquid vaporization and reduces energy consumption at the time of heating.
Moreover, aerosol generation devices such as electronic cigarette are in a constant need for miniaturization, portability and construction optimization to provide devices that are the most convenient to carry without being less effective or less safe. A problem that arises with aerosol generation devices comprising a removable consumable article is to improve the hold of the removable consumable article in place on the device without increasing the manufacturing effort and complexifying the structure of the device so that the consumable article remains fixed on the device during for example manipulation, use or transport of the device.
EP Patent publication No. 3 456 213 A1, this reference herewith incorporated by reference in its entirety, discloses a heater element including a plurality of pins/needles fixed at the base of the heater element fixedly coupled with the power side of an electronic cigarette, the pins extending through corresponding perforations of a heating chamber holding the tobacco substrate for vaporization by the pins.
EP Patent publication No. 2 519 122 B1, this reference herewith incorporated by reference in its entirety, shows a heater for heating an aerosol-forming substrate comprising a plurality of elongate heating elements arranged in an elongated array arranged to heat the substrate to form an aerosol.
The systems described in these publications may not effectively distribute heat in a precise manner to specific parts of the consumable article.
SUMMARYIt is one aspect of the present disclosure to provide a heater for an aerosol generation device, and a system comprising the heater and the consumable article that overcomes the above challenges.
Preferably, the heater for an aerosol generation device, which is intended to connect with a consumable article of e-liquid, comprises, a frame, a plurality of elongated heating elements extending substantially perpendicularly to a horizontal plane in which lies the frame, wherein the elongated heating elements are configured to engage with corresponding grooves arranged on a surface of a shell of the consumable article at a time of connecting.
In embodiments of the present invention, the elongated heating elements are configured to slide into the corresponding grooves and hold the consumable article.
In embodiments of the present disclosure, the elongated heating elements are further configured to hold the consumable article by form-fit.
In embodiments of the present disclosure, a number of elongated heating elements is smaller or equal to a number of grooves.
In embodiments of the present invention, at least one of the elongated heating elements comprises a heating material, the heating material comprising a first zone at a first extremity of the at least one of the elongated heating elements and of a second zone at a second extremity of the at least one of the elongated heating elements.
In embodiments of the present invention, the first zone is different from the second zone in that it enables to reach a first temperature different from a second temperature that is reached in the second zone.
In embodiments of the present disclosure, at least one of the elongated heating elements is further configured to deliver a heat gradient comprising a first temperature at the first extremity of the at least one of the elongated heating elements and a second temperature at the second extremity of the at least one heating element.
In embodiments of the present invention, the heat gradient is configured to selectively vaporize substances from the e-liquid when the heater comes in contact with it.
In embodiments of the present invention, the heat gradient is configured to generate at least one heating site located on the at least one of the elongated heating elements to heat a specific location in the consumable article.
In embodiments of the present disclosure, the at least one of the elongated heating elements comprises a heating part comprising the heating material and a diffusing part comprising a diffusing material configured to transfer the heat produced by the heating material and diffuse the heat by conduction hence generating a heat gradient.
In embodiments of the present invention, the at least one of the elongated heating elements comprises at least one patterned zone configured to have a higher electrical current density.
In embodiments of the present disclosure, the patterned zone comprises at least one serpentine and/or at least one pattern of holes and/or at least one pattern of slots.
In embodiments of the present invention, the frame comprises the heating material and at least one of the elongated heating elements comprises the diffusing material configured to transfer the heat produced by the heating material.
In embodiments of the present invention, the heater is configured to generate at least one heating site located on the at least one of the elongated heating elements (12) to heat a specific location in the consumable article (20).
In embodiments of the present disclosure, the at least one heating site is further configured to heat a wicking element arranged in the consumable article.
In embodiments of the present invention, the at least one heating site is further configured to heat a specific part of the wicking element.
In embodiments of the present invention, the at least one heating site is located adjacent to an air channel arranged on the consumable article.
In embodiments of the present invention, the first temperature T1 is different from the second temperature T2.
Another aspect of the present invention relates to providing a consumable article for an aerosol generation device that overcomes the above challenges.
Preferably, the consumable article for an aerosol generation device, which is intended to connect with the heater according to the present disclosure, is configured to contain an e-liquid and has a shell comprising grooves arranged on the surface of the shell, wherein the grooves are configured to engage with corresponding elongated heating elements arranged on the heater, at a time of connecting.
In embodiments, the grooves are configured to receive elongated heating elements from the heater.
In embodiments, the consumable article is further configured to be held by the elongated heating elements by form-fit.
In embodiments a number of grooves is equal or bigger to a number of elongated heating elements.
In embodiments the consumable article further comprises at least a wicking element configured to be in contact with the elongated heating elements when these are engaged and thereby present e-liquid to be heated and transformed into aerosol.
It is another aspect of the present invention to provide a system for an aerosol generation device comprising the heater and the consumable article according to the present disclosure that overcomes the above challenges.
Preferably, the system for an aerosol generation device comprises the heater according to the present invention comprising a plurality of elongated heating elements. The system further comprises the consumable article according the invention having a shell comprising grooves arranged on the surface of the shell, wherein the elongated heating elements are engaged in the grooves to secure the heater to the consumable article.
The above and other objects, features and advantages of the present invention and the manner of realizing them will become more apparent, and the invention itself will best be understood from a study of the following description with reference to the attached drawings showing some preferred embodiments of the invention.
BRIEF DESCRIPTION OF THE DRAWINGSThe accompanying drawings, which are incorporated herein and constitute part of this specification, illustrate the presently preferred embodiments of the invention, and together with the general description given above and the detailed description given below, serve to explain features of the invention.
FIG.1 shows a two-part schematic view of a heater for an aerosol generation device comprising elongated heating elements;
FIG.2 shows a schematic top-view of a heater for an aerosol generation device comprising elongated heating elements;
FIG.3 shows a schematic view of a heating element;
FIG.4 depicts a schematic view of a consumable article for an aerosol generation device comprising grooves arranged on a surface of a consumable article shell;
FIG.5 shows a top schematic view of a consumable article for an aerosol generation device comprising grooves arranged on a surface of a consumable article shell;
FIG.6 depicts a schematic view of a consumable article for an aerosol generation device surrounded by a plurality of elongated heating elements, according to an example embodiment of the invention;
FIG.7 depicts a top view of the consumable article depicted inFIG.6;
FIG.8 depicts a single elongated heating element indicating opposite zones that may heat at different temperatures, according to an example embodiment of the invention;
FIG.9 depict a heater element with a plurality of elongated heating elements, as used inFIG.6;
FIG.10 shows a schematic representation of an unconnected system comprising a heater comprising elongated heating elements and a consumable article comprising grooves arranged on a surface of a consumable article shell;
FIG.11 depicts a schematic representation of a connected system comprising a heater comprising elongated heating elements and a consumable article comprising grooves arranged on a surface of a consumable article shell;
FIG.12 shows a schematic top-view of a connected system comprising a consumable article comprising grooves arranged on a surface of a consumable article shell and a heater (visible in transparency below the consumable article) comprising elongated heating elements;
FIG.13 shows a preferred embodiment of the consumable article and heater fromFIG.12, further comprising a wicking element according to an example embodiment of the invention;
FIG.14 shows a simplified view ofFIG.13;
FIG.15 shows a preferred embodiment of the consumable article and heater fromFIG.12, further comprising a wicking element according to an example embodiment of the invention;
FIG.16 shows a simplified view ofFIG.15; and
FIGS.17 to20 show a plurality of examples in which the elongated heating elements and/or the consumable article are configured to releasably hold and maintain the consumable article on the heating element.
Herein, identical reference numerals are used, where possible, to designate identical elements that are common to the figures. Also, the images are simplified for illustration purposes and may not be depicted to scale.
DETAILED DESCRIPTION OF SEVERAL EMBODIMENTSIt is a first object of the invention to provide aheater10 for an aerosol generation device according toFIGS.1 to3, which is intended to connect, in use, with at least a battery part of the aerosol generation device on the one hand and with aconsumable article20 of vaporizable material according toFIGS.4 and5 on the other hand.
The term vaporizable material is used to designate any material that is vaporizable at a temperature up to 400° C., preferably up to 350° C., for example aerosol generating liquid, gel, wax and the like.
Theconsumable article20 may be in the format of any of a capsule, a cartridge, a pod or other liquid-containing devices for removable connection to an aerosol generation device and for intended connection with aheater10 for an aerosol generation device. Theconsumable article20 may be discarded or refilled once the vaporizable material has been consumed by the user.
As depicted inFIGS.1 and2, theheater10 comprises aframe11 and a plurality ofelongated heating elements12 extending substantially perpendicularly relatively to a horizontal plane in which lies theframe11.
Theheater10 may be an electric heater working on the principle of Joule heating in which the passage of an electric current, for example, in at least one of the elongated heating elements and/or in theframe11 produces heat.
Theframe11 may be for example a ring, a plate or any suitable element that may carry theelongated heating elements12.
Theframe11 may alternatively be an electric heater configured to produce heat when an electric current is flowing in theframe11.
Theelongated heating elements12 may be welded on theframe11 in a way to extend substantially perpendicularly relatively to a horizontal plane in which lies theframe11.
Referring now also toFIG.4, theelongated heating elements12 are configured to engage withcorresponding grooves22 arranged on a surface of ashell21 of theconsumable article20, at the time of the intended connection between theheater10 and theconsumable article20.
Theelongated heating elements12 are positioned on theframe11 to correspond to thegrooves22 arranged on the surface of theshell21 of theconsumable article20.
The engagement of theelongated heating elements12 withcorresponding grooves22 arranged on the surface of theshell21 of theconsumable article20 further enables to hold theconsumable article20 onto theheater10, for example by a clamping effect implemented through a mechanical friction effect applied by the heating elements to theshell21, and/or by a spring effect between the heating elements that then may possess either protuberating parts that engage in corresponding cavities of the sheel. or cavities that engage with corresponding protuberating parts of the shell.
Theelongated heating elements12 are further configured to slide into thecorresponding grooves22 of theshell21 of theconsumable article20 to hold theconsumable article20.
Distances between each of theelongated heating elements12 and a center of theframe11, or among each other on a circumference defined by theframe11, may be smaller than distances betweencorresponding grooves22 of theconsumable article20 and a center axis A of theconsumable article20, or the corresponding grooves among each other on a circumference defined by the outer periphery of theconsumable article20, enabling theelongated heating elements12 to hold theconsumable article20 using the clamping effect when theheater10 engages with theconsumable article20.
Theelongated heating elements12 may be flexible to engage in thegrooves22 of theconsumable article20 and exert the clamping effect by spring forces of the elongated heating elements as exerted on theconsumable article20, enabling to hold theconsumable article20 at the time of the intended connection between theheater10 and theconsumable article20.
Theelongated heating elements12 may also extend from theframe11 slightly inclined toward the center of theframe11 in order to exert a pressure on thegrooves22 of theconsumable article20 when theheater10 is connected to theconsumable article20 enabling the holding of theconsumable article20.
Theelongated heating elements12 may also hold theconsumable article20 by form-fit.
The number ofelongated heating elements12 may be smaller or equal to the number ofgrooves22 arranged on theshell21 of theconsumable article20.
As depicted inFIG.3, at least one of theelongated heating elements12 further comprises aheating material13.
In another embodiment, theframe11 further comprise theheating material13.
Theheating material13 may comprise metallic material such as kanthal, nickel, nickel-chromium, titanium, nichrome, tungsten, stainless steel or any material having required heating properties working on the principle of Joule heating for example, in which the passage of an electric current produces heat. In one embodiment, at least one of theelongated heating elements12 comprise theheating material13 having the same density along the at least one of theelongated heating elements12 enabling to provide a constant heat along the least one of theelongated heating elements12.
The diffusing material may comprise metallic material which exhibits appropriate thermal conduction properties.
In another embodiment, theheating material13 comprises a first zone ofheating material13 at afirst extremity14 of the at least one of theelongated heating elements12 and a second zone ofheating material13 at asecond extremity15 of the at least one of theelongated heating elements12.
Preferably, the first zone ofheating material13 is different from the second zone of the heating material in that the first zone enables to reach a first temperature T1 different from a second temperature T2 that can be reached in the second zone.
As a consequence, the at least one of theelongated heating elements12 is further configured to deliver a heat gradient comprising the first temperature T1 at thefirst extremity14 and the second temperature T2 at thesecond extremity15.
The first temperature T1 may be different from the second temperature T2. For example, the first temperature T1 may be higher or lower than the second temperature T2. Preferentially, the second temperature T2 is higher than the first temperature T1.
In another embodiment, the heat gradient may be obtained, for example, by creating at least one patterned zone on at least one of theelongated heating elements12 configured to have higher electrical current densities thus generating locally higher temperature.
The at least one patterned zone may comprise serpentine or an appropriate pattern of holes/slots distributed along the at least one patterned zone, wherein the distance between two holes/slots is reduced compared to the remaining part of theelongated heating element12. Each zone with reduced distance is subject to higher current density in such a way that when current flows through the at least one of theelongated heating elements12, the temperature is higher these zones. As described above, components of the vaporizable e-liquid will be therefore selectively heated. Lower temperature's components will vaporize first while the vaporizable material propagate through theelongated heating elements12.
In another embodiment, at least one of theelongated heating elements12 may comprise two different parts: a heating part comprising theheating material13 and a diffusing part comprising a diffusing material. The heating part enables to generate heat when the electrical current is flowing. The diffusing part enables to transfer the heat produced by the heating part and diffuse the heat by conduction hence generating a heat gradient. The area of the diffusing part which is the most distant from the heating part receives less energy (i.e. less heat) than the area of the diffusing part which is the closest from the heating part of the at least one of theelongated heating elements12. Hence components of the vaporizable e-liquid will be therefore selectively heated. Lower temperature's components will vaporize first while the vaporizable material propagates through the second part of the at least one of theelongated heating elements12.
The heat gradient may be further modulated by defining a specific shape or form of the diffusing part of the at least one of theelongated heating elements12.
In another embodiment, theframe11 may comprise theheating material13 and be configured to generate heat. At least one of theelongated heating elements12 may comprise the diffusing material and be configured to transfer the heat produced by theframe11 and diffuse the heat by conduction hence generating a heat gradient along the at least one of theelongated heating elements12 as the first14 and second15 extremities of the at least one of theelongated heating elements12 received different amount of energy or heat.
In another embodiment, the density of theheating material13 of theframe11 around theelongated heating elements12 may be different in order to provide different levels of heat to the differentelongated heating elements12.
The heat gradient is configured to selectively vaporize substances from the e-liquid that comes in contact with theheater10.
The heat gradient is further configured to generate at least one heating site located on the at least one of the heating elements to heat a specific location in theconsumable article20.
The at least one heating site may be further configured to heat a wicking element (not represented) arranged in theconsumable article20. The at least one heating site may also be configured to heat a specific part of the wicking element.
In a further embodiment, the at least one heating site may be generated on the at least one of the heating elements in a way to be located adjacent to anair channel24 arranged on theconsumable article20 when theheater10 is connected to theconsumable article20.
In another embodiment, at least one of theelongated heating elements12 may also be used as a transportation means of the e-liquid.
The at least one of theelongated heating elements12 may further comprises a wicking element or a mesh arranged on or in at least one of theelongated heating elements12 configured to transport and deliver a controlled quantity of the e-liquid from theconsumable article20 or from the reservoir to the at least one heating site generated on the at least one of theelongated heating elements12 enabling the vaporization of the e-liquid.
It is a second object of the invention to provide aconsumable article20 according toFIGS.4 and5 for an aerosol generation device, which is configured to contain an e-liquid, and which is intended to connect with theheater10 according toFIGS.1 to3.
Theconsumable article20 may comprise anyone of the list comprising a capsule, a cartridge, a pod or other liquid-containing devices for removable connection to an aerosol generation device.
Theconsumable article20 may be discarded or refilled once the e-liquid has been consumed by the user.
Theconsumable article20 may comprise a reservoir (not represented) arranged inside theconsumable article20 and intended to contain the e-liquid.
Theconsumable article20 further comprises ashell21 comprisinggrooves22 arranged on the surface of theshell21.
Thegrooves22 may comprise recesses arranged on the surface of theshell21 having dimension and shape enabling to receive theelongated heating elements12 arranged on theheater10.
Thegrooves22 may also comprise openings arranged in theshell21 of theconsumable article20 having dimension and shape enabling to receive theelongated heating elements12 arranged on theheater10.
Thegrooves22 arranged on the surface of theshell21 are configured to engage with correspondingelongated heating elements12 arranged on theheater10, at the time of intended connection between theconsumable article20 and theheater10.
Thegrooves22 are further configured to receiveelongated heating elements12 from theheater10.
Thegrooves22 are positioned on theshell21 of theconsumable article20 to correspond to theelongated heating elements12 arranged on theheater10 in order to enable the intended connection between theconsumable article20 and theheater10.
The number ofgrooves22 arranged on the surface of theshell21 of theconsumable article20 is equal or greater than the number ofelongated heating elements12 of theheater10.
Theconsumable article20 may comprise at least oneairflow channel23 arranged on or in theconsumable article20. The at least oneairflow channel23 is intended to collect and receive vaporized e-liquid, i.e., e-liquid which is heated and hence aerosolized by theelongated heating elements12, and directs the aerosolized e-liquid toward an intended mouthpiece to be inhaled by an intended user (mouthpiece and user not represented inFIG.4).
Theconsumable article20 may also comprise at least oneair channel24 arranged on or in theconsumable article20.
The at least oneair channel24 is in connection to the at least oneairflow channel23. The at least oneair channel24 is further configured to receive e-liquid which is aerosolized by theelongated heating elements12 and to direct the aerosolized e-liquid toward the at least oneairflow channel23.
Theconsumable article20 may further comprise at least one wicking element such as a porous material piece and/or a mesh (not represented) configured to capture and transfer the e-liquid from theconsumable article20, for example from the reservoir of theconsumable article20 to the at least one of theelongated heating elements12, preferably to the at least one heating site. The wicking element further enables to control the quantity of vaporizable material transferred from theconsumable article20 to the elongated heating element.
The at least one wicking element may be located on the of theconsumable article20, for example on theshell21 of theconsumable article20, in at least one of thegrooves22 arranged on theconsumable article20.
The at least one wicking element may be further positioned in a way that at the time of connection between theheater10 and theconsumable article20, at least one of theelongated heating elements12 is positioned between theshell21 of theconsumable article20 and the wicking element.
The at least one wicking element may be also positioned in a way that at the time of connection between theheater10 and theconsumable article20, at least one of theelongated heating elements12 is inserted into the at least one wicking element.
The wicking element which has the function to transfer the e-liquid from theconsumable article20 to at least one of the heating elements, preferably to the at least one heating site.
FIGS.6 and7 illustrate an example embodiment in which theconsumable article20 comprises theshell21, which in this example is surrounded by a cylindrically shaped wickingelement60. Aheater element62 comprises a plurality ofelongated heating elements61. Theconsumable article20 is connected to theheater element62 with theelongated heating elements61 at the periphery of the consumable element and in mechanical contact with the cylindrically shaped wickingelement60. Theelongated heating elements61 may for example hold theconsumable article20 by means of mechanical friction with thewicking element60. Theelongated heating elements61 may be configured to heat e-liquid in the mesh, for example with a homogenous temperature over the whole surface of the respective elongated heating elements or with a differential temperature from T2 at one extremity of each theelongated heating element61, as illustrated inFIGS.8, to T1 at an opposite extremity of theelongated heating element61, with T2 being greater than T1. By heating the e-liquid in the mesh, the aerosol is generated inside the wickingelement60.FIG.7 contains a top view of the assembly fromFIG.6, in which 3 elongatedheating elements61 are distributed around thecylindrical wicking element60 distant at substantially equal angles among each other, i.e., at 120°. In the present example, theelongated heating elements61 avoid penetrating inside and/or piercing theconsumable article20. Hence theelongated heating elements61 do not interfere with a consumable article's sealing mechanism and allow for a simpler technical construction.
It is to be noted that the main function of theelongated heating elements61 is to transfer heat. As an auxiliary function, theelongated heating elements61 may be used to hold and/or maintain theconsumable article20.
It is to be noted that theelongated heating elements61 may be wear parts, and this need to be periodically changed in theheater62, or together with theheater62.
FIG.9 shows theheater62 with the3elongated heating elements61 extending perpendicularly away from the horizontal place of theheater62. In a preferred embodiment, theelongated heating elements61 may comprise a mechanism configured to open and close theelongated heating elements61 away and toward the wicking element.
As depicted inFIGS.10 to12, it is another object of the invention to provide asystem30 for an aerosol generation device comprising aheater10 according to the present description and comprising a plurality ofelongated heating elements12 and aconsumable article20 as described in the present description, having ashell21 comprisinggrooves22 arranged on the surface of theshell21, theelongated heating elements12 being engaged in thegrooves22 to secure theheater10 to theconsumable article20.
At the time of inserting theheater10 in theconsumable article20, theelongated heating elements12 are received by the correspondinggrooves22 arranged on theshell21 of theconsumable article20. Theelongated heating elements12 slide into the grove and allow to hold theconsumable article20 in place, for example by form-fit.
As obvious for a skilled person in the field of aerosol generating devices, theheater10 shall be mounted in electrical connection with a power delivery component of an aerosol generating device such as a battery to allow it to heat e-liquid in theconsumable article20. Such mounting is not represented in the attached drawings for the sake of clarity.
As shown inFIG.12, when theheater10 is connected to theconsumable article20, theelongated heating elements12 are positioned next to the at least oneair channel24.
Preferentially, the at least one heating site generated by the heat gradient of theelongated heating elements12 is located adjacent to theair channel24 arranged on theconsumable article20 hence allowing theair channel24 to receive and collect the aerosolized e-liquid and direct it to an intended mouthpiece and eventually to an intended user for inhalation (mouthpiece and user not illustrated inFIG.12).
FIG.13 shows a preferred embodiment of the consumable article and heater fromFIG.12, further comprising awicking element130 inside theshell21. Thewicking element130 contacts theelongated heating elements12, which are respectively engaged between thegrooves22 and thewicking element130. Theheating element12 may exert a mechanical friction with the wicking element130 (and optionally with the grooves22) which enables to maintain theconsumable article20.
FIG.14 is a simplified view ofFIG.13, in which the proportions of sizes are not necessarily respected, showing only thewicking element130, represented as a ring in this view, and running at an outside of theelongated heating elements12, outside meaning on the side away from thecenter140 of the consumable article.
FIG.15 shows a preferred embodiment of the consumable article and heater fromFIG.12, further comprising awicking element150 inside theshell21. Thewicking element150 contacts theelongated heating elements12, which are respectively engaged in thegrooves22 and externally to thewicking element150. Theheating elements12 may exert a mechanical friction and pressure onto thewicking element150 at the circumference of the consumable article, which enables to maintain theconsumable article20 in place on the heating element (not illustrated).
FIG.16 is a simplified view ofFIG.15, in which the proportions of sizes are not necessarily respected, showing only thewicking element150, represented as a ring in this view, and running at an inside of theelongated heating elements12, inside meaning on the side showing towards thecenter140 of the consumable article.
FIGS.17 to20 show a plurality of examples in which the elongated heating elements and/or the consumable article are configured to releasably hold and maintain the consumable article on the heating element.
InFIG.17, awall170 of agroove22 comprises aprotuberating part171. The left-side part of the figure illustrates anelongated heating element172 being slid relative to thewall170 indirection173 at a time where the consumable article is positioned on the heating element (both not illustrated inFIG.17). The right-side part of the figure illustrates theelongated heating element172 having acavity174 corresponding to theprotuberating part171, engaging with theprotuberating part171 by spring force exerted from theelongated heating element172 once the consumable article is positioned on the heating element.
InFIG.18, awall180 of agroove22 comprises acavity181. The left-side part of the figure illustrates anelongated heating element182 being slid relative to thewall180 indirection183 at a time where the consumable article is positioned on the heating element (both not illustrated inFIG.18). The right-side part of the figure illustrates theelongated heating element182 having aprotuberating part184 corresponding to thecavity181, engaging with thecavity181 by spring force exerted from theelongated heating element182 once the consumable article is positioned on the heating element.
FIG.19 is a frontal view of ashell21 with agroove22 formed in the wall of theshell21. Anelongated heating element190 is configured to be inserted into thegroove22 at a time where the consumable article is positioned on the heating element (both not illustrated inFIG.19), and form-fit with it. The form-fit designates the interaction between theindividual groove22 and the correspondingelongated heating element190. The geometrical shape of the elongated heating element replicates the geometrical shape of the groove with a relative small difference, whereby thewidth191 of thegroove22 is large enough to allow to engage theelongated heating element190 with awidth192, but small enough to generate a friction to maintain the consumable article in place.
FIG.20 is a further frontal view of ashell21 with agroove22 formed in the wall of theshell21. Anelongated heating element200, preferably of flexible nature such as that of a spring, having acavity201, is configured to be inserted into thegroove22 at a time where the consumable article is positioned on the heating element (both not illustrated inFIG.20), and form-fit with it. The groove has a shape complementary to that of theelongated heating element200, i.e., it comprises aprotuberating element202, or locking pin, that engages with thecavity201. This type of form-fit may be called bayonet style locking.
The details and embodiments described above for an aerosol generation device are applicable to an electronic cigarette comprising aheater10, aconsumable article20 or asystem30 comprising aheater10 and aconsumable article20.
While the invention has been disclosed with reference to certain preferred embodiments, numerous modifications, alterations, and changes to the described embodiments, and equivalents thereof, are possible without departing from the sphere and scope of the invention. Accordingly, it is that the invention not be limited to the described embodiments and be given the broadest reasonable interpretation in accordance with the language of the appended claims.