RU2794984C1 - Aerosol generating system, mouthpiece for aerosol generating article and method of assembly of the mouthpiece - Google Patents

Abstract

FIELD: aerosol-generating systems.

SUBSTANCE: group of inventions relates to a mouthpiece for an aerosol-generating article, an aerosol-generating system, and a method for assembling the mouthpiece. The mouthpiece for an aerosol generating article is formed from at least two main parts that are axially inserted into each other to create an aerosol flow path. The two main parts are movable in the axial direction relative to each other between the first assembled position and the second assembled position. The mouthpiece additionally contains an activatable element for modifying characteristics of the aerosol upon activation, while moving the two main parts from the first assembled position to the second assembled position, the activatable element is activated. The mouthpiece further comprises an inlet end configured to guide an aerosol flow into the mouthpiece and an outlet end configured to discharge an aerosol flow from the mouthpiece, wherein the aerosol flow path extends between the inlet end and the outlet end. The mouthpiece is designed in such a way that the direction of the aerosol flow is reversed at least once between the inlet end and the outlet end, while the activated element is held in place by clamping in the mouthpiece.

EFFECT: improved cooling and homogenization of the aerosol inside the mouthpiece for the aerosol generating article.

14 cl, 7 dwg, 1 tbl

Description

The present invention relates to a mouthpiece for an aerosol generating article, an aerosol generating system comprising a mouthpiece and an aerosol generating article, and a method for assembling a mouthpiece.

To date, a number of different aerosol generating systems are known in which respirable vapors are generated in various ways (see, for example, WO 2016/096780, A24F 47/00, 06/23/2016). In so-called electronic evaporators, the liquid substrate forming the aerosol is evaporated by means of electrical heating devices. In "heat without combustion" devices, the solid aerosol-forming substrate, which may contain tobacco material, is heated but not combusted. These "heat without burning" devices may be electrical. There are also systems of the "heating without combustion" type, in which heat is generated by combustion or chemical reactions.

In all these systems, the heating element vaporizes the aerosol-forming substrate and then the aerosol is formed. Aerosol formation, in particular droplet size, total suspended particles (TPM), aerosol temperature, or aerosol homogeneity, depends on a variety of factors such as downstream cooling of the air relative to the aerosol-forming substrate and air pressure. Aerosol formation also depends on external conditions such as temperature, air pressure or humidity. Accordingly, changes in mean temperature and humidity can be significant factors influencing aerosol formation in aerosol generating systems.

It would be desirable to provide a mouthpiece for an aerosol generating system to improve aerosol generation.

It would be desirable to provide a mouthpiece for the aerosol generating system that allows the aerosol generating system to achieve optimized aerosol generation regardless of external or climatic conditions.

It is desirable to provide a customizable mouthpiece that can be configured to influence the characteristics of the aerosol and conform to user preferences. In particular, it would be desirable to provide an adjustable mouthpiece in which the cooling characteristics and flavoring characteristics can be adjusted during use to suit the preferences of the user.

According to one embodiment of the present invention, a mouthpiece is provided for an aerosol generating article. The mouthpiece is made of at least two main parts that can be inserted axially into each other to create an aerosol flow path. The two main parts are movable in the axial direction relative to each other between the first assembled position and the second assembled position. The mouthpiece additionally contains an activatable element for modifying the characteristics of the aerosol upon activation. The activated element is activated by moving the two main parts from the first assembled position to the second assembled position.

The mouthpiece according to the present invention makes it possible to control the air flow along the air flow path from the aerosol generation point of the aerosol generating device towards the outlet of the mouthpiece. In particular, the ability to activate an activatable element can be used to personalize inhalation conditions that modify parameters of the generated aerosol such as aroma, droplet size, temperature, or total particulate yield.

The aerosol flow path in the mouthpiece may comprise a plurality of channels. The total length of the aerosol flow path is determined by the sum of the lengths of each individual channel. The channels may be arranged such that the total length of the aerosol flow path may be greater than the axial length of the mouthpiece. Thus, due to the particular arrangement of the channels, an effective lengthening of the air flow path is achieved relative to conventional mouthpieces containing only one, usually linear, air flow channel. The lengthening of the air flow path improves the cooling and homogenization of the aerosol.

The channels may be tubular channels. The tubular channels may be arranged coaxially within the mouthpiece. The inlet end of the mouthpiece may be in direct fluid communication with a tubular channel located along the central longitudinal axis of the mouthpiece. The air flow path may then continue through one or more additional coaxially arranged channels. The outermost of the coaxially arranged tubular channels is in direct fluid communication with the outlet end of the mouthpiece.

The coaxial arrangement of the tubular channels provides a clear and symmetrical airflow path through the mouthpiece. This symmetrical design ensures optimal and reproducible inhalation conditions.

In different embodiments of the mouthpiece, the direction of flow of the aerosol through the plurality of channels may vary. The direction of aerosol flow through the plurality of channels may be reversed between each successive aerosol flow channels. In this case, the aerosol is directed through the mouthpiece from the inlet end to the outlet end many times in such a way that a significant elongation of the air flow path is achieved.

A plurality of expansion chambers may be provided within the airflow path of the mouthpiece. These expansion chambers may be provided at reversal points between two successive tubular channels.

Expansion chambers can affect the performance of the aerosol by temporarily increasing the volume of airflow and reversing the direction of airflow. This makes it possible to obtain a homogeneous aerosol with the desired particle size. In addition, the expansion may provide a decrease in the temperature of the aerosol.

The outermost tubular passage may extend to the mouthpiece outlet end and may define a circular or ring-shaped mouthpiece outlet end.

The mouthpiece may have any desired external shape. Preferably, the mouthpiece has an outer shape that matches the outer shape of the aerosol generating devices to which the mouthpiece is attached. For example, the mouthpiece may have a tubular or cylindrical outer shape and may define a central longitudinal axis.

The outlet end of the mouthpiece may have any other desired shape and may be formed by the outer wall of the mouthpiece. The mouthpiece may include a cavity recessed from the outlet end of the mouthpiece. This cavity may also be referred to as a cavity. Such a volume recess can be considered as the final expansion chamber of the air flow path.

Accordingly, said volumetric recess may contribute to the homogenization of the aerosol and, in particular, may provide cooling of the aerosol. The recessed outlet may achieve improved aerosol production at the outlet end of the mouthpiece and thus other user experience and satisfaction.

The mouthpiece may include a central channel which extends from the inlet end and which diverges radially in the direction of the aerosol flow. The mouthpiece may further comprise at least two tubular channels which are arranged coaxially with respect to the central channel and which are in fluid communication with the central channel. The direction of the aerosol flow through these three channels can be reversed between each successive aerosol flow channels. Accordingly, in the central passage, the direction of air flow is from the inlet end to the outlet end. In the adjacent second tubular passage, the direction of air flow is reversed and passes from the outlet to the inlet end. At the end of the second tube channel, the direction of the air flow is again reversed so that in the third tube channel the direction of the air flow is again towards the outlet end. At the end of the third channel, the aerosol is released from the mouthpiece.

In this case, the aerosol is directed through the mouthpiece from the inlet end to the outlet end many times in such a way that a significant elongation of the air flow path is achieved.

To further modify the characteristics of the aerosol, the mouthpiece contains an activatable element. The activated element may contain a substance to modify the properties of the aerosol that is directed through the mouthpiece. Prior to activation of the activated element, the interaction of this substance with the aerosol is prevented. After activation of the activated element, the substance is released, and gets the opportunity to modify the property of the aerosol. This property may be one or more of the organoleptic property of the aerosol, the spatial property of the aerosol, and the aroma of the aerosol.

The activated element may contain a destructible capsule, which contains a substance for modifying the specified property of the aerosol. Upon activation of the activatable element, the capsule of the encapsulated liquid may be broken and the previously encapsulated liquid may be released in the vicinity of the activatable element.

The activated element may contain a substrate. The substrate may be used as a support for the capsule holding the encapsulated liquid. The capsule holding the encapsulated liquid may be attached to the substrate.

The substrate may be porous and capable of absorbing the previously encapsulated liquid upon activation. The porous material may absorb at least a portion of the previously encapsulated liquid. The porous material may be configured to absorb all of the previously encapsulated liquid. By making the substrate capable of absorbing all of the previously encapsulated liquid released, the liquid will be securely retained in the mouthpiece at all times. In particular, the exit of liquid from the mouthpiece through the outlet end can be avoided.

The substrate may be a low density material that has a low resistance to draw (RTD). Due to its low draw resistance, the substrate does not significantly affect the overall draw resistance of the mouthpiece.

The substrate may be positioned to pass at least partially across the cross section of the aerosol flow path in the mouthpiece when the main parts are in the second assembled position. The substrate may pass through at least 50 percent of the cross section of the aerosol flow path. The substrate may pass through at least 70 percent of the cross section of the aerosol flow path. The substrate may pass through at least 90 percent of the cross section of the aerosol flow path. The substrate may pass through substantially the entire cross section of the aerosol flow path. By positioning the substrate at least partially within the flow path of the aerosol, the aerosol is at least partially directed through the substrate to facilitate interaction between the previously encapsulated material and the aerosol.

The activation agent used to activate the activated element may depend on the type of encapsulation agent used. Gel capsules, such as hard or soft shell gelatin capsules, can be activated by rupturing the shell. The shell can be torn apart by pressing or piercing.

In embodiments, one of the main parts may contain a piercing element for activating the activated element. The piercing element can pierce the capsule holding the encapsulated liquid upon activation.

The piercing element may be an elongated element. The piercing element may extend parallel to the longitudinal axis of the mouthpiece. The piercing element may be conical or may be needle shaped.

The piercing element may be designed such that when the two main parts are in the first assembled position, the apex of the piercing element is located at a distance from the activated element. After the relative axial movement of the two main parts to the second assembled position, the piercing element can be directed towards the activated element and can be made to activate the activated element. The piercing element may be configured to break the capsule of the activated element when the two main parts are moved to the second assembled position.

The piercing element may be designed to help create an aerosol flow path within the mouthpiece. The piercing element may be formed in such a way as to guide the aerosol towards the substrate. For example, in the second assembled position, the tip of the conical piercing element may completely penetrate the substrate of the activatable element and may even extend into an area upstream of the activatable element. The tip of the piercing element can then be used to direct the aerosol into the impregnated areas of the substrate. Thus, the piercing element can be used to improve the interaction between the aerosol and the previously encapsulated liquid.

The mouthpiece may be made from any suitable material such as polymeric materials. Suitable materials include polymer compounds for use in food and/or medical applications, in particular thermoplastic polyester elastomers (TPC-ET), polyoxymethylene compounds (POM), high density polyethylene (HDPE), low density polyethylene (LDPE), polybutylene terephthalate (PBT). ), acrylic multipolymer, biodegradable polylactic acid (PLA), or cycloolefin copolymer (COC).

The mouthpiece may be made of at least two main parts, which are configured to be inserted into each other in the axial direction. These two main parts can be designed in such a way that when they are inserted into each other in the axial direction, these two main parts form an air flow path.

The mouthpiece may be formed by an inner part and an outer part. The outer portion may define a central inner channel and may include a tubular outer wall which simultaneously forms the outer wall of the mouthpiece.

The interior may have a hollow cylindrical shape with a side wall, one open end and one closed end. The inner part can be inserted axially into the outer part in such a way that the side wall of the inner part is located between the central channel and the outer wall of the outer part. In this case, a second channel is formed between the side wall of the inner part and the central channel. The third channel is formed between the side wall of the inner part and the outer wall of the outer part. Thus, by assembling the two parts, a channel is formed for the air to flow from the inlet end through the center channel and further through the second and third channels towards the outlet end of the mouthpiece. This two-piece design facilitates the manufacture of a mouthpiece with a labyrinth-like airflow path.

This two-piece design allows individual parts to be produced using traditional and well known blow molding processes. Such processes may be more convenient to use than other possible manufacturing techniques required to manufacture the mouthpiece in accordance with the present invention in the form of a one-piece product.

The two main parts of the mouthpiece can be assembled in the first position. The two main parts are additionally movable in the axial direction to the second assembled position. In order to achieve this functionality, the two main parts of the mouthpiece may have respective interlocking structures. These interlocking structures are engaged with each other when assembled to form a mouthpiece with predetermined dimensions. In addition, the interlocking structures help hold the mouthpiece in its assembled configuration. In particular, interlocking structures are provided which prevent accidental separation of the mouthpiece during use.

The interlocking structures may include one or more protrusions and one or more locking cavities that are located on the facing surfaces of the main parts of the mouthpiece. The interlocking structures may comprise three protrusions and three corresponding locking cavities which are located on the facing surfaces of the main parts of the mouthpiece. After assembly, each of one or more protrusions located on the surface of one part engages with a corresponding locking cavity located on the surface of another part of the mouthpiece. The protrusions can be located on the outer surface of the side wall of the inner part, and the locking cavities can be located on the inner surface of the outer wall of the outer part.

The protrusions and locking cavities can be evenly distributed around the circumference of the two parts so that after assembly the two parts are firmly held in a coaxially aligned position. The interlocking structures may be in the form of two or more sets of interlocking structures that are located at different axial positions along the side walls of the two main parts of the mouthpiece. Each set may consist of three or more protrusions and locking cavities. The provision of two or more sets of interlocking structures allows the two main parts to be securely held in a predetermined mutual orientation.

The implementation of mutually interlocking structures in the form of corresponding protrusions and locking cavities allows a simple but reliable production of a two-component mouthpiece. The connection between the mutually interlocking structures can be made in such a way as to prevent accidental separation of the mouthpiece into parts and at the same time facilitate targeted disassembly by controlled separation of the two parts.

Additional interlocking structures may be provided along the longitudinal axis of the mouthpiece to enable the two main parts of the mouthpiece to be assembled in two different axial positions. For example, the outer part may contain three sets of locking cavities that will interact with two sets of protrusions located on the inner part. The inner part can be inserted into the outer part in such a way that two sets of protrusions of the inner part engage with the first and second set of fixing cavities of the outer part to form a mouthpiece with the first configuration. In an alternative embodiment, the inner portion may be inserted such that the two sets of protrusions of the inner portion engage with the second and third set of locking cavities of the outer portion to form a mouthpiece with a second configuration. The dimensions of the airflow channels formed in the mouthpiece in the first and second configurations are different from each other. Accordingly, a mouthpiece with adjustable airflow control characteristics and general aerosol production parameters is obtained.

In the above example, the inner part may be located at two predetermined axial positions relative to the outer part of the mouthpiece. The provision of additional sets of interlocking structures allows additional predetermined axial positions of the inner part relative to the outer part to be established. This allows you to further increase the versatility of the corresponding mouthpiece.

An activated element is provided in the mouthpiece. When the two main parts are assembled in the first position, the activated element can be located between the respective structures of the two main parts. The element to be activated may be held in place by clamping in the mouthpiece. The element to be activated may be held in place by being clamped in one of the main parts, or by being sandwiched between the respective structures of the two main parts.

In one embodiment, the activated element may be located in one of the expansion chambers, which are formed at the reversal points between successive longitudinal channels. For example, in the first assembled position of the two main parts of the mouthpiece, the activated element may be located in the first expansion chamber in the direction of the flow of the aerosol through the mouthpiece. The activated element may be sized to match the inner diameter of the inner body and may be retained within the inner body by friction.

The piercing element may be located at the closed end of the inner body of the mouthpiece. The piercing element can extend parallel to the longitudinal axis of the mouthpiece, while the pointed end extends into the internal volume of the mouthpiece. With axial movement of the two main parts to the second assembled position, the piercing element formed at the closed end of the inner main part can move in the direction of the activated element until the activated element is sandwiched between the piercing element of the inner part and the side walls of the central channel of the outer main part mouthpiece. After completion of the axial movement to the second assembled position, the piercing element is moved further in the direction of the activated element, which leads to the rupture of the capsule wall and the release of the encapsulated liquid.

The released liquid is dispersed in the substrate of the element to be activated and can then interact with any aerosol directed through the mouthpiece after this activation procedure. The released liquid can be dispersed throughout the substrate. The released liquid may be dispersed partially throughout the substrate. The released liquid can be dispersed substantially throughout the substrate. Dispersing the released liquid throughout the substrate increases the available contact area for liquid-aerosol interaction.

The mouthpiece of the present invention can be used with any type of aerosol generating devices and aerosol generating articles. In this regard, the inlet end of the mouthpiece may comprise a connecting portion configured to attach the mouthpiece to such an aerosol generating device or to an aerosol generating article.

Any suitable mechanism may be used in the connection portion which allows the user to releasably attach the mouthpiece to the aerosol generating device or aerosol generating article. For example, the connecting part may be a pin/socket connection. A pin/socket connection may be suitably shaped elements configured to form a friction fit connection or a form-fit connection.

A friction fit connection may be formed by appropriately shaped connecting elements that can be inserted into one another and held in the connected position by friction between the connecting elements.

A form-fitting connection can be obtained by providing threaded portions on the connecting elements forming a threaded connection. Such connectors may comprise 90° male/female fittings that quickly and securely attach to each other by rotating the connectors 90°. Of course, connecting elements with large angles of rotation can also be used. The male/female screw connectors provide secure and leak-tight connections and allow the mouthpiece to be sealed to the aerosol generating device or aerosol generating article.

The connecting part may be in the form of a pharmaceutical or medical type connection. Pharmaceutical or medical grade compounds can further increase the density of the generated aerosol.

The invention also relates to an aerosol generating system comprising a mouthpiece as described above and an aerosol generating device and/or aerosol generating article. The mouthpiece and the aerosol generating device or aerosol generating article have respective fittings for releasably attaching the mouthpiece to the aerosol generating device or aerosol generating article. The aerosol generating device or aerosol generating article may be any of the currently available aerosol generating devices or aerosol generating articles, including, without limitation, heat non-burning (HNB) type products or evaporative systems. , in which the aerosol is formed from the liquid substrate that forms the aerosol.

The present invention also relates to a method for assembling a mouthpiece. The method includes providing an outer portion, the outer portion defining a central inner channel and a tubular outer wall of the mouthpiece. The method further includes providing an interior, the interior having a hollow cylindrical shape with a side wall, one open end and one closed end. The method further includes providing an activatable element.

The element to be activated is inserted into the inside of the mouthpiece. The inner part is inserted axially into the outer part in such a way that the side wall of the inner part is located between the central channel and the outer wall of the outer part. The activated element may be located in the first expansion chamber formed in the mouthpiece in the direction of the aerosol flow.

The inner part and the outer part used in the method of forming the mouthpiece may correspond to the inner part and the other part described above. In particular, these parts can be provided with mutually interlocking structures, so that when they are assembled, a mouthpiece with predetermined dimensions and a predetermined air flow path is obtained.

The following is a non-exhaustive list of non-limiting examples. Any one or more features of these examples may be combined with any one or more features of another example, embodiment, or aspect described herein.

EXAMPLE A Mouthpiece for an aerosol generating article, wherein the mouthpiece is formed from at least two main parts which can be axially inserted into each other to create an aerosol flow path,

wherein the two main parts are movable in the axial direction relative to each other between the first assembled position and the second assembled position,

moreover, the mouthpiece further contains an activated element for modifying the characteristics of the aerosol upon activation, and

in this case, when the two main parts are moved from the first assembled position to the second assembled position, the activated element is activated.

EXAMPLE B A mouthpiece according to example A, wherein the activatable element comprises a substrate and an encapsulated liquid.

EXAMPLE C A mouthpiece according to one of the previous examples, wherein upon activation of the element to be activated, the encapsulated liquid is at least partially released to the substrate.

Example D A mouthpiece according to one of the previous examples, wherein one of the main parts contains a piercing element which pierces the activatable element to activate the activatable element.

EXAMPLE E A mouthpiece according to one of the previous examples, wherein the piercing element is an elongated element which extends parallel to the longitudinal axis of the mouthpiece.

Example F Mouthpiece according to one of the previous examples, wherein the substrate is a low density material and the activatable element is positioned to pass at least partially through the cross section of the aerosol flow path when the main parts are in the second assembled position .

Example G. A mouthpiece according to one of the previous examples, comprising an inlet end configured to enter an aerosol stream into the mouthpiece, an outlet end configured to discharge an aerosol stream from the mouthpiece, wherein the aerosol flow path extends between the inlet end and the outlet end, and wherein the mouthpiece is configured such that the flow direction of the aerosol is reversed at least once between the inlet end and the outlet end, with the substrate held in place by pinching in the mouthpiece.

Example H A mouthpiece according to one of the previous examples, wherein the mouthpiece is formed from an outer portion and an inner portion, the outer portion defining a central inner channel and a tubular outer wall of the mouthpiece, and the inner portion having a hollow cylindrical shape with a side wall, one open end and one closed end, and the inner part is inserted in the axial direction into the outer part so that the side wall of the inner part is located between the Central channel and the outer wall of the outer part.

Example I A mouthpiece according to example H, wherein the piercing element is located at the closed end of the inner portion, with the apex of the piercing element extending into a region located upstream of the actuated element when the inner and outer portion of the mouthpiece are assembled in the second position.

EXAMPLE J A mouthpiece according to one of the previous examples, wherein the two main parts of the mouthpiece have respective interlocking structures which engage with each other to form a mouthpiece of given dimensions.

Example K A mouthpiece according to one of the previous examples, wherein the interlocking structures comprise one or more protrusions and one or more locking cavities which are located on the facing surfaces of the mouthpiece main parts.

Example L A mouthpiece according to one of the previous examples, wherein the interlocking structures comprise one or more sets of interlocking structures such that the two main parts can be assembled in two or more different mutual axial positions.

Example M An aerosol generating system comprising an aerosol generating device and a mouthpiece according to one of the previous examples.

Example N An aerosol generating system according to example M, wherein the aerosol generating device and the mouthpiece comprise corresponding fittings such that the mouthpiece can be detachably attached to the aerosol generating device.

Example O. Method for assembling a mouthpiece, including the steps:

(a) providing an outer portion, wherein the outer portion defines a central inner channel and a tubular outer wall of the mouthpiece,

(b) providing an interior, the interior having a hollow cylindrical shape with a side wall, one open end and one closed end,

(c) providing an activatable element,

(d) assembling the outer part, the inner part and the activated element by inserting the activated element into the inner part and inserting the inner part axially into the outer part so that the side wall of the inner part is located between the central channel and the outer wall of the outer part.

The features described in relation to one aspect can be equally applied to other aspects of the present invention.

The present invention will now be described solely by way of example with reference to the accompanying drawings, in which:

in FIG. 1 shows a mouthpiece according to the present invention;

in FIG. 2 shows a mouthpiece according to the present invention with a two-piece casing;

in FIG. 3 is a three-dimensional view and planar projection of the outlet end of the mouthpiece shown in FIG. 1;

in FIG. 4 shows two embodiments of an activatable element;

in FIG. 5 shows the activation of the activated element;

in FIG. 6 shows the dimensions of the mouthpiece shown in FIG. 5;

in FIG. 7 shows an aerosol generating device with the mouthpiece shown in FIG. 5.

On FIG. 1 shows a mouthpiece 10 according to the present invention. The mouthpiece is tubular and defines an airflow path 20 between inlet end 12 and outlet end 14. FIG. 1, an inlet end 12 is provided on the left side of the mouthpiece 10 and is provided with a fitting 16 for connecting the mouthpiece 10 to the aerosol generating device. An outlet end 14 is provided at the opposite end of the mouthpiece 10 and is configured to allow the user to take it into the mouth for inhalation.

The air flow path 20 between the inlet end 12 and the outlet end 14 comprises a plurality of tubular passages 22, 23, 24 that are arranged concentrically and coaxially. The tubular channels 22, 23, 24 are arranged such that the direction of air flow is reversed twice before the aerosol exits the mouthpiece 10 at the outlet end 14.

The mouthpiece 10 includes a central channel that extends from the inlet end 12 and extends towards the outlet end 14 of the mouthpiece. The central channel 22 diverges radially in the direction of the aerosol flow. In other words, the diameter of the central channel 22 increases in the direction of the aerosol flow. At the end of the central channel 22, the direction of the aerosol flow is reversed, and then the aerosol is directed through the coaxially located middle channel 23 towards the inlet end 12 of the mouthpiece 10. At the end of the middle channel 23, the direction of the aerosol flow is reversed again, and then the aerosol is directed through the coaxially located the outer tubular passage 23 towards the outlet end 14 of the mouthpiece 10. Finally, the aerosol is discharged through the outlet end 14 for inhalation by the user.

With the design of the present invention, the length of the airflow path 20 through the mouthpiece 10 is effectively increased, allowing additional time for heat energy to dissipate. In addition, expansion chambers 25, 26 are provided at points of change of direction between successive channels 22, 23, 24. These expansion chambers 25, 26 assist in cooling and homogenizing the aerosol.

In addition, an actuated element 28 is provided which is located within the expansion chamber 25. An actuated element 28 is located within the airflow path 20 and is used to further modify the aerosol characteristic.

The maze-like airflow path 20 in the mouthpiece 10 can be obtained by fabricating the mouthpiece casing 10 in two pieces, as shown in FIG. 2A. The first or outer portion 30 of the mouthpiece 10 is shown on the left side of FIG. 2a and defines the inlet 32, the connecting part 34, the central channel 22 and the tubular outer wall 36 of the mouthpiece 10. The interior 40 of the mouthpiece 10 is generally U-shaped. It has a hollow cylindrical shape with a side wall 42, one open end 44 and one closed end 46. A piercing element 84 is provided on the inside of the closed end 46. The piercing element 84 is tapered with a pointed end. The pointed end is directed towards the central channel 22 of the outer part 30. The inner part 40 is designed in such a way that it can be inserted axially with its open end 44 into the outer part 30 of the mouthpiece 10.

In addition to the outer part 30 and the inner part 40, an actuated element 28 is provided. When assembling the mouthpiece 10, the actuated element 28 is inserted between the inner part 30 and the outer part 40 of the mouthpiece 10. This can be achieved by first inserting the actuated element 28 into the inner volume of the inner part 40. Then the inner part 40 containing the activatable element 28 can be inserted into the outer part 30 of the mouthpiece 10. expansion chamber 25 of the mouthpiece 10 as shown in FIG. 2b.

The two main parts 30, 40 of the mouthpiece 10 have respective interlocking structures 50 which engage with each other when the mouthpiece 10 is fully assembled. The interlocking structures 50 are designed to support the mouthpiece 10 in a fully assembled configuration during use by the user. The interlocking structures 50 further provide a mouthpiece 10 with predetermined dimensions.

In the embodiment shown in FIG. 2, the inner portion 40 of the mouthpiece 10 includes projections 52 located on the outer circumference of the side wall 42 of the inner portion 40. The outer portion 30 includes corresponding locking cavities 54 that are located on the inner surface 38 of the outer wall 36 of the outer portion 30. When fully assembled, the projections 52 the inner part 40 engages with the locking cavities 54 of the other part 30 as shown in FIG. 2B. The inner part 40 of the mouthpiece 10 contains two sets of protrusions 52A, 52, which are located at a distance from each other in the axial direction. The outer part 30 of the mouthpiece 10 contains three sets of locking cavities 54A, 54B, 54C, which are also located in the axial direction at a distance from each other.

Each set of protrusions 52A, 52B consists of three or more protrusions 52 distributed equidistantly around the circumference of the side wall 36 of the interior 30. Accordingly, each set of locking cavities 54A, 54B, 54C is composed of three or more locking cavities 54 distributed equidistantly along the inner surface 38 of the outer wall 36 of the outer part 30. In the first assembled position of the two main parts, as shown in FIG. 2b, the protrusions 52A, 52B are engaged with the locking cavities 54A, 54B. In this axial position of the two main parts, the activated element is not activated. As a result of the movement of the inner part 40 in the axial direction to the second assembled position, in which the protrusions 52A, 52B engage with the locking cavities 54B, 54C, the activated element can be activated, as will be further described below in connection with FIG. 5.

On FIG. 3 shows a perspective view and a side view of a mouthpiece 10 according to the present invention. In the perspective view in Fig. 3A shows the overall tubular shape of the mouthpiece 10 and the spherical shape of the closed end 46 of the interior 40. In the side view of FIG. 3B shows the circumferential distribution of a set of interlocking structures 50 consisting of three elements that are distributed equidistantly around the circumference of the inner portion 40 and the outer portion 30, respectively.

On FIG. 4 shows embodiments of an activatable element 28. The activatable element 28 comprises a substrate 80 and a capsule 82, 83 which is adhered to the substrate. Substrate 80 is in the form of a disc of low density cellulose acetate tow. Due to its low density, the substrate material has low draw resistance and may not cause a noticeable increase in the overall draw resistance of the mouthpiece 10 and/or the aerosol generating system 100 in which the mouthpiece 10 is intended to be used.

As shown in FIG. 4a, the capsule 82 provided on the actuated member 28 may be in the form of a substantially spherical gel capsule. Capsule 82 may be filled with water, fragrance, or any other active liquid. Capsule 82 may be centrally located on substrate 80 and may be attached to substrate 80 using standard adhesives that are suitable for this purpose. The diameter S of the substrate and the diameter T of the spherical capsule 82 may have the dimensions shown in Table 1 below.

In an alternative embodiment, the capsule may be in the form of a flat capsule 83 as shown in the embodiment in FIG. 4b. The flat capsule 83 can also be adhered to the substrate 80 using conventional adhesives known to those skilled in the art. The flat capsule 83 of FIG. 4b may contain the same liquid as the spherical capsule 82 according to the embodiment of FIG. 4a. The diameter S of the substrate 80 and the diameter U of the flat capsule 83 may have the dimensions shown in Table 1 below.

A piercing member 84 is provided to activate the actuated member 28 to release the encapsulated liquid. The following will explain the piercing member 84 and the piercing process with reference to FIG. 5. In FIG. 5 shows the mouthpiece according to FIG. 2, in which the outer portion 30 of the mouthpiece 10 contains three sets of locking cavities 54. As shown in FIG. 5a, the mouthpiece 10 can be assembled in a first assembled position in which two sets of protrusions 52A, 52B are engaged with the first and second set of locking cavities 54A, 54B. In this first assembled position, the actuated element 2 8 is located in the expansion chamber 25 and not yet activated.

To activate the actuated element 28, the mouthpiece 10 can be brought into a second assembled position, as shown in FIG. 5b. In this second assembled position, the inner portion 40 is moved axially further into the outer portion 30 until the two sets of protrusions 52A, 52B engage the second and third sets of locking cavities 54B, 54C. In this second retracted position, the piercing element 84, which is located at the closed end 46 of the interior 40 of the mouthpiece 10, moves in the direction of the actuated element 28. As shown in FIG. 5b, the piercing element 84 completely penetrates the capsule 82 and the substrate 80, and the piercing element 84 even slightly extends into the central channel 22 formed in the center of the outer portion 30 of the mouthpiece 10. Thus, the piercing element 84 extends into the area located upstream of the activated element 28. The piercing element 84 has ruptured the outer shell of the capsule 82. Thereby, the previously encapsulated liquid is released and dispersed into the surrounding substrate 80. through the substrate 80 impregnated with liquid. Thus, once activated element 28 is activated, the previously encapsulated liquid can be used to modify the aerosol and can provide the desired effect during a user session.

Both parts 30, 40 of the mouthpiece 10 shown in the figures are made of thermoplastic polyester elastomers, food grade polymer compounds being used in accordance with good manufacturing practice. On FIG. 6 again shows the inside and outside of the mouthpiece 10 and the preferred ranges for the sizes shown in FIG. 4 and 6 are listed in Table 1 below.

On FIG. 7 shows an aerosol generating system 100 comprising an aerosol generating device 60 and a mouthpiece 10 as described above. The aerosol generating device 60 comprises a housing 62 with a power supply 64, control electronics 66, an aerosol generating substrate 68, and an aerosol generating unit 70. The aerosol generating unit 70 includes an aerosol generating chamber 72 which is provided at one end of the aerosol generating device 60. This end of the aerosol generating device 60 further comprises a connecting part 74 to which the mouthpiece 10 described above can be connected. When the mouthpiece 10 is connected to the aerosol generating device 60, an air flow path 20 is formed from the aerosol generation chamber 72 through the mouthpiece 10. This allows the user to inhale the aerosol generated in the aerosol generation chamber 72 through the mouthpiece 10.

Claims (18)

1. A mouthpiece for an aerosol generating article, wherein the mouthpiece is formed from at least two main parts that are axially insertable into each other to create an aerosol flow path, the two main parts being axially movable relative to each other between the first collected position and the second collected position, and the mouthpiece additionally contains an activated element for modifying the characteristics of the aerosol upon activation, while moving the two main parts from the first assembled position to the second assembled position, the activated element is activated, and the mouthpiece additionally contains an inlet end , configured to inlet an aerosol flow into the mouthpiece, and an outlet end configured to discharge the aerosol flow from the mouthpiece, wherein the aerosol flow path extends between the inlet end and the outlet end, the mouthpiece being configured such that the direction of the aerosol flow is at least is reversed once between the inlet end and the outlet end, with the activated element held in place by clamping in the mouthpiece. 2. A mouthpiece according to claim. 1, characterized in that the activated element contains the substrate and enclosed in the capsule liquid, and the substrate is held in place by pinching in the mouthpiece. 3. The mouthpiece according to claim. 2, characterized in that upon activation of the activated element, the encapsulated liquid is at least partially released to the substrate. 4. Mouthpiece according to claim. 2 or 3, characterized in that the substrate is a low density material, and the activated element is located so as to pass at least partially through the cross section of the aerosol flow path when the main parts are in the second collected position. 5. The mouthpiece according to one of the preceding claims, characterized in that one of the main parts contains a piercing element that pierces the activated element with the activation of the activated element. 6. Mouthpiece according to claim. 5, characterized in that the piercing element is an elongated element that runs parallel to the longitudinal axis of the mouthpiece. 7. Mouthpiece according to one of the preceding claims, characterized in that the mouthpiece consists of an outer part and an inner part, wherein the outer part forms a central inner channel and a tubular outer wall of the mouthpiece, and the inner part has a hollow cylindrical shape with a side wall, one open end and one closed end, and the inner part is inserted in the axial direction into the outer part so that the side wall of the inner part is located between the Central channel and the outer wall of the outer part. 8. The mouthpiece according to claim 7, characterized in that a piercing element is provided at the closed end of the inner part, and the top of the piercing element extends into the area located upstream from the activated element when the inner part and the outer part of the mouthpiece are assembled in the second position. 9. Mouthpiece according to one of the preceding claims, characterized in that the two main parts of the mouthpiece have respective interlocking structures that engage with each other to obtain a mouthpiece with predetermined dimensions. 10. A mouthpiece according to claim 9, characterized in that the interlocking structures comprise one or more protrusions and one or more locking cavities, which are located on the surfaces of the main parts of the mouthpiece facing each other. 11. Mouthpiece according to claim 9 or 10, characterized in that the interlocking structures comprise one or more sets of interlocking structures such that the two main parts are assembled in two or more different mutual axial positions. 12. An aerosol generating system comprising an aerosol generating device and a mouthpiece according to one of the preceding claims. 13. An aerosol generating system according to claim 12, characterized in that the aerosol generating device and the mouthpiece comprise respective connecting parts, such that the mouthpiece can be detachably connected to the aerosol generating device. 14. A method for assembling a mouthpiece, including the steps: (a) providing an outer portion, the outer portion defining a central inner channel and a tubular outer wall of the mouthpiece; (b) providing an interior, the interior having a hollow cylindrical shape with a side wall, one open end and one closed end; (c) providing an activatable element; (d) assembling the outer part, the inner part and the activated element by inserting the activated element into the inner part and inserting the inner part axially into the outer part in such a way that the side wall of the inner part is located between the central channel and the outer wall of the outer part, and the mouthpiece is additionally contains an inlet end configured to inlet the aerosol flow into the mouthpiece, and an outlet end configured to discharge the aerosol flow from the mouthpiece, while the aerosol flow path passes between the inlet end and the outlet end, while the mouthpiece is designed in such a way that the direction of the aerosol flow is reversed at least once between the inlet end and the outlet end, while the activated element is held in place by clamping in the mouthpiece.

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